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The JUCE cross-platform C++ framework, with DISTRHO/KXStudio specific changes
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JUCE/src/native/windows/juce_win32_AudioCDReader.cpp

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  1. /*

  2.   ==============================================================================

  3. 

  4.    This file is part of the JUCE library - "Jules' Utility Class Extensions"

  5.    Copyright 2004-9 by Raw Material Software Ltd.

  6. 

  7.   ------------------------------------------------------------------------------

  8. 

  9.    JUCE can be redistributed and/or modified under the terms of the GNU General

  10.    Public License (Version 2), as published by the Free Software Foundation.

  11.    A copy of the license is included in the JUCE distribution, or can be found

  12.    online at www.gnu.org/licenses.

  13. 

  14.    JUCE is distributed in the hope that it will be useful, but WITHOUT ANY

  15.    WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR

  16.    A PARTICULAR PURPOSE.  See the GNU General Public License for more details.

  17. 

  18.   ------------------------------------------------------------------------------

  19. 

  20.    To release a closed-source product which uses JUCE, commercial licenses are

  21.    available: visit www.rawmaterialsoftware.com/juce for more information.

  22. 

  23.   ==============================================================================

  24. */

  25. 

  26. // (This file gets included by juce_win32_NativeCode.cpp, rather than being

  27. // compiled on its own).

  28. #if JUCE_INCLUDED_FILE && JUCE_USE_CDBURNER

  29. 

  30. 

  31. //***************************************************************************

  32. //       %%% TARGET STATUS VALUES %%%

  33. //***************************************************************************

  34. #define STATUS_GOOD         0x00    // Status Good

  35. #define STATUS_CHKCOND      0x02    // Check Condition

  36. #define STATUS_CONDMET      0x04    // Condition Met

  37. #define STATUS_BUSY         0x08    // Busy

  38. #define STATUS_INTERM       0x10    // Intermediate

  39. #define STATUS_INTCDMET     0x14    // Intermediate-condition met

  40. #define STATUS_RESCONF      0x18    // Reservation conflict

  41. #define STATUS_COMTERM      0x22    // Command Terminated

  42. #define STATUS_QFULL        0x28    // Queue full

  43. 

  44. //***************************************************************************

  45. //      %%% SCSI MISCELLANEOUS EQUATES %%%

  46. //***************************************************************************

  47. #define MAXLUN              7       // Maximum Logical Unit Id

  48. #define MAXTARG             7       // Maximum Target Id

  49. #define MAX_SCSI_LUNS       64      // Maximum Number of SCSI LUNs

  50. #define MAX_NUM_HA          8       // Maximum Number of SCSI HA's

  51. 

  52. //***************************************************************************

  53. //     %%% Commands for all Device Types %%%

  54. //***************************************************************************

  55. #define SCSI_CHANGE_DEF     0x40    // Change Definition (Optional)

  56. #define SCSI_COMPARE        0x39    // Compare (O)

  57. #define SCSI_COPY           0x18    // Copy (O)

  58. #define SCSI_COP_VERIFY     0x3A    // Copy and Verify (O)

  59. #define SCSI_INQUIRY        0x12    // Inquiry (MANDATORY)

  60. #define SCSI_LOG_SELECT     0x4C    // Log Select (O)

  61. #define SCSI_LOG_SENSE      0x4D    // Log Sense (O)

  62. #define SCSI_MODE_SEL6      0x15    // Mode Select 6-byte (Device Specific)

  63. #define SCSI_MODE_SEL10     0x55    // Mode Select 10-byte (Device Specific)

  64. #define SCSI_MODE_SEN6      0x1A    // Mode Sense 6-byte (Device Specific)

  65. #define SCSI_MODE_SEN10     0x5A    // Mode Sense 10-byte (Device Specific)

  66. #define SCSI_READ_BUFF      0x3C    // Read Buffer (O)

  67. #define SCSI_REQ_SENSE      0x03    // Request Sense (MANDATORY)

  68. #define SCSI_SEND_DIAG      0x1D    // Send Diagnostic (O)

  69. #define SCSI_TST_U_RDY      0x00    // Test Unit Ready (MANDATORY)

  70. #define SCSI_WRITE_BUFF     0x3B    // Write Buffer (O)

  71. 

  72. //***************************************************************************

  73. //     %%% Commands Unique to Direct Access Devices %%%

  74. //***************************************************************************

  75. #define SCSI_COMPARE        0x39    // Compare (O)

  76. #define SCSI_FORMAT         0x04    // Format Unit (MANDATORY)

  77. #define SCSI_LCK_UN_CAC     0x36    // Lock Unlock Cache (O)

  78. #define SCSI_PREFETCH       0x34    // Prefetch (O)

  79. #define SCSI_MED_REMOVL     0x1E    // Prevent/Allow medium Removal (O)

  80. #define SCSI_READ6          0x08    // Read 6-byte (MANDATORY)

  81. #define SCSI_READ10         0x28    // Read 10-byte (MANDATORY)

  82. #define SCSI_RD_CAPAC       0x25    // Read Capacity (MANDATORY)

  83. #define SCSI_RD_DEFECT      0x37    // Read Defect Data (O)

  84. #define SCSI_READ_LONG      0x3E    // Read Long (O)

  85. #define SCSI_REASS_BLK      0x07    // Reassign Blocks (O)

  86. #define SCSI_RCV_DIAG       0x1C    // Receive Diagnostic Results (O)

  87. #define SCSI_RELEASE        0x17    // Release Unit (MANDATORY)

  88. #define SCSI_REZERO         0x01    // Rezero Unit (O)

  89. #define SCSI_SRCH_DAT_E     0x31    // Search Data Equal (O)

  90. #define SCSI_SRCH_DAT_H     0x30    // Search Data High (O)

  91. #define SCSI_SRCH_DAT_L     0x32    // Search Data Low (O)

  92. #define SCSI_SEEK6          0x0B    // Seek 6-Byte (O)

  93. #define SCSI_SEEK10         0x2B    // Seek 10-Byte (O)

  94. #define SCSI_SEND_DIAG      0x1D    // Send Diagnostics (MANDATORY)

  95. #define SCSI_SET_LIMIT      0x33    // Set Limits (O)

  96. #define SCSI_START_STP      0x1B    // Start/Stop Unit (O)

  97. #define SCSI_SYNC_CACHE     0x35    // Synchronize Cache (O)

  98. #define SCSI_VERIFY         0x2F    // Verify (O)

  99. #define SCSI_WRITE6         0x0A    // Write 6-Byte (MANDATORY)

  100. #define SCSI_WRITE10        0x2A    // Write 10-Byte (MANDATORY)

  101. #define SCSI_WRT_VERIFY     0x2E    // Write and Verify (O)

  102. #define SCSI_WRITE_LONG     0x3F    // Write Long (O)

  103. #define SCSI_WRITE_SAME     0x41    // Write Same (O)

  104. 

  105. //***************************************************************************

  106. //   %%% Commands Unique to Sequential Access Devices %%%

  107. //***************************************************************************

  108. #define SCSI_ERASE          0x19    // Erase (MANDATORY)

  109. #define SCSI_LOAD_UN        0x1b    // Load/Unload (O)

  110. #define SCSI_LOCATE         0x2B    // Locate (O)

  111. #define SCSI_RD_BLK_LIM     0x05    // Read Block Limits (MANDATORY)

  112. #define SCSI_READ_POS       0x34    // Read Position (O)

  113. #define SCSI_READ_REV       0x0F    // Read Reverse (O)

  114. #define SCSI_REC_BF_DAT     0x14    // Recover Buffer Data (O)

  115. #define SCSI_RESERVE        0x16    // Reserve Unit (MANDATORY)

  116. #define SCSI_REWIND         0x01    // Rewind (MANDATORY)

  117. #define SCSI_SPACE          0x11    // Space (MANDATORY)

  118. #define SCSI_VERIFY_T       0x13    // Verify (Tape) (O)

  119. #define SCSI_WRT_FILE       0x10    // Write Filemarks (MANDATORY)

  120. 

  121. //***************************************************************************

  122. //      %%% Commands Unique to Printer Devices %%%

  123. //***************************************************************************

  124. #define SCSI_PRINT          0x0A    // Print (MANDATORY)

  125. #define SCSI_SLEW_PNT       0x0B    // Slew and Print (O)

  126. #define SCSI_STOP_PNT       0x1B    // Stop Print (O)

  127. #define SCSI_SYNC_BUFF      0x10    // Synchronize Buffer (O)

  128. 

  129. //***************************************************************************

  130. //     %%% Commands Unique to Processor Devices %%%

  131. //***************************************************************************

  132. #define SCSI_RECEIVE        0x08    // Receive (O)

  133. #define SCSI_SEND           0x0A    // Send (O)

  134. 

  135. //***************************************************************************

  136. //    %%% Commands Unique to Write-Once Devices %%%

  137. //***************************************************************************

  138. #define SCSI_MEDIUM_SCN     0x38    // Medium Scan (O)

  139. #define SCSI_SRCHDATE10     0x31    // Search Data Equal 10-Byte (O)

  140. #define SCSI_SRCHDATE12     0xB1    // Search Data Equal 12-Byte (O)

  141. #define SCSI_SRCHDATH10     0x30    // Search Data High 10-Byte (O)

  142. #define SCSI_SRCHDATH12     0xB0    // Search Data High 12-Byte (O)

  143. #define SCSI_SRCHDATL10     0x32    // Search Data Low 10-Byte (O)

  144. #define SCSI_SRCHDATL12     0xB2    // Search Data Low 12-Byte (O)

  145. #define SCSI_SET_LIM_10     0x33    // Set Limits 10-Byte (O)

  146. #define SCSI_SET_LIM_12     0xB3    // Set Limits 10-Byte (O)

  147. #define SCSI_VERIFY10       0x2F    // Verify 10-Byte (O)

  148. #define SCSI_VERIFY12       0xAF    // Verify 12-Byte (O)

  149. #define SCSI_WRITE12        0xAA    // Write 12-Byte (O)

  150. #define SCSI_WRT_VER10      0x2E    // Write and Verify 10-Byte (O)

  151. #define SCSI_WRT_VER12      0xAE    // Write and Verify 12-Byte (O)

  152. 

  153. //***************************************************************************

  154. //      %%% Commands Unique to CD-ROM Devices %%%

  155. //***************************************************************************

  156. #define SCSI_PLAYAUD_10     0x45    // Play Audio 10-Byte (O)

  157. #define SCSI_PLAYAUD_12     0xA5    // Play Audio 12-Byte 12-Byte (O)

  158. #define SCSI_PLAYAUDMSF     0x47    // Play Audio MSF (O)

  159. #define SCSI_PLAYA_TKIN     0x48    // Play Audio Track/Index (O)

  160. #define SCSI_PLYTKREL10     0x49    // Play Track Relative 10-Byte (O)

  161. #define SCSI_PLYTKREL12     0xA9    // Play Track Relative 12-Byte (O)

  162. #define SCSI_READCDCAP      0x25    // Read CD-ROM Capacity (MANDATORY)

  163. #define SCSI_READHEADER     0x44    // Read Header (O)

  164. #define SCSI_SUBCHANNEL     0x42    // Read Subchannel (O)

  165. #define SCSI_READ_TOC       0x43    // Read TOC (O)

  166. 

  167. //***************************************************************************

  168. //      %%% Commands Unique to Scanner Devices %%%

  169. //***************************************************************************

  170. #define SCSI_GETDBSTAT      0x34    // Get Data Buffer Status (O)

  171. #define SCSI_GETWINDOW      0x25    // Get Window (O)

  172. #define SCSI_OBJECTPOS      0x31    // Object Postion (O)

  173. #define SCSI_SCAN           0x1B    // Scan (O)

  174. #define SCSI_SETWINDOW      0x24    // Set Window (MANDATORY)

  175. 

  176. //***************************************************************************

  177. //    %%% Commands Unique to Optical Memory Devices %%%

  178. //***************************************************************************

  179. #define SCSI_UpdateBlk      0x3D    // Update Block (O)

  180. 

  181. //***************************************************************************

  182. //    %%% Commands Unique to Medium Changer Devices %%%

  183. //***************************************************************************

  184. #define SCSI_EXCHMEDIUM     0xA6    // Exchange Medium (O)

  185. #define SCSI_INITELSTAT     0x07    // Initialize Element Status (O)

  186. #define SCSI_POSTOELEM      0x2B    // Position to Element (O)

  187. #define SCSI_REQ_VE_ADD     0xB5    // Request Volume Element Address (O)

  188. #define SCSI_SENDVOLTAG     0xB6    // Send Volume Tag (O)

  189. 

  190. //***************************************************************************

  191. //     %%% Commands Unique to Communication Devices %%%

  192. //***************************************************************************

  193. #define SCSI_GET_MSG_6      0x08    // Get Message 6-Byte (MANDATORY)

  194. #define SCSI_GET_MSG_10     0x28    // Get Message 10-Byte (O)

  195. #define SCSI_GET_MSG_12     0xA8    // Get Message 12-Byte (O)

  196. #define SCSI_SND_MSG_6      0x0A    // Send Message 6-Byte (MANDATORY)

  197. #define SCSI_SND_MSG_10     0x2A    // Send Message 10-Byte (O)

  198. #define SCSI_SND_MSG_12     0xAA    // Send Message 12-Byte (O)

  199. 

  200. 

  201. //***************************************************************************

  202. //      %%% Request Sense Data Format %%%

  203. //***************************************************************************

  204. typedef struct {

  205.  BYTE  ErrorCode;       // Error Code (70H or 71H)

  206.  BYTE  SegmentNum;      // Number of current segment descriptor

  207.  BYTE  SenseKey;        // Sense Key(See bit definitions too)

  208.  BYTE  InfoByte0;       // Information MSB

  209.  BYTE  InfoByte1;       // Information MID

  210.  BYTE  InfoByte2;       // Information MID

  211.  BYTE  InfoByte3;       // Information LSB

  212.  BYTE  AddSenLen;       // Additional Sense Length

  213.  BYTE  ComSpecInf0;     // Command Specific Information MSB

  214.  BYTE  ComSpecInf1;     // Command Specific Information MID

  215.  BYTE  ComSpecInf2;     // Command Specific Information MID

  216.  BYTE  ComSpecInf3;     // Command Specific Information LSB

  217.  BYTE  AddSenseCode;    // Additional Sense Code

  218.  BYTE  AddSenQual;      // Additional Sense Code Qualifier

  219.  BYTE  FieldRepUCode;   // Field Replaceable Unit Code

  220.  BYTE  SenKeySpec15;    // Sense Key Specific 15th byte

  221.  BYTE  SenKeySpec16;    // Sense Key Specific 16th byte

  222.  BYTE  SenKeySpec17;    // Sense Key Specific 17th byte

  223.  BYTE  AddSenseBytes;   // Additional Sense Bytes

  224. } SENSE_DATA_FMT;

  225. 

  226. //***************************************************************************

  227. //       %%% REQUEST SENSE ERROR CODE %%%

  228. //***************************************************************************

  229. #define SERROR_CURRENT      0x70    // Current Errors

  230. #define SERROR_DEFERED      0x71    // Deferred Errors

  231. 

  232. //***************************************************************************

  233. //      %%% REQUEST SENSE BIT DEFINITIONS %%%

  234. //***************************************************************************

  235. #define SENSE_VALID         0x80    // Byte 0 Bit 7

  236. #define SENSE_FILEMRK       0x80    // Byte 2 Bit 7

  237. #define SENSE_EOM           0x40    // Byte 2 Bit 6

  238. #define SENSE_ILI           0x20    // Byte 2 Bit 5

  239. 

  240. //***************************************************************************

  241. //     %%% REQUEST SENSE SENSE KEY DEFINITIONS %%%

  242. //***************************************************************************

  243. #define KEY_NOSENSE         0x00    // No Sense

  244. #define KEY_RECERROR        0x01    // Recovered Error

  245. #define KEY_NOTREADY        0x02    // Not Ready

  246. #define KEY_MEDIUMERR       0x03    // Medium Error

  247. #define KEY_HARDERROR       0x04    // Hardware Error

  248. #define KEY_ILLGLREQ        0x05    // Illegal Request

  249. #define KEY_UNITATT         0x06    // Unit Attention

  250. #define KEY_DATAPROT        0x07    // Data Protect

  251. #define KEY_BLANKCHK        0x08    // Blank Check

  252. #define KEY_VENDSPEC        0x09    // Vendor Specific

  253. #define KEY_COPYABORT       0x0A    // Copy Abort

  254. #define KEY_EQUAL           0x0C    // Equal (Search)

  255. #define KEY_VOLOVRFLW       0x0D    // Volume Overflow

  256. #define KEY_MISCOMP         0x0E    // Miscompare (Search)

  257. #define KEY_RESERVED        0x0F    // Reserved

  258. 

  259. //***************************************************************************

  260. //      %%% PERIPHERAL DEVICE TYPE DEFINITIONS %%%

  261. //***************************************************************************

  262. #define DTYPE_DASD          0x00    // Disk Device

  263. #define DTYPE_SEQD          0x01    // Tape Device

  264. #define DTYPE_PRNT          0x02    // Printer

  265. #define DTYPE_PROC          0x03    // Processor

  266. #define DTYPE_WORM          0x04    // Write-once read-multiple

  267. #define DTYPE_CROM          0x05    // CD-ROM device

  268. #define DTYPE_SCAN          0x06    // Scanner device

  269. #define DTYPE_OPTI          0x07    // Optical memory device

  270. #define DTYPE_JUKE          0x08    // Medium Changer device

  271. #define DTYPE_COMM          0x09    // Communications device

  272. #define DTYPE_RESL          0x0A    // Reserved (low)

  273. #define DTYPE_RESH          0x1E    // Reserved (high)

  274. #define DTYPE_UNKNOWN       0x1F    // Unknown or no device type

  275. 

  276. //***************************************************************************

  277. //      %%% ANSI APPROVED VERSION DEFINITIONS %%%

  278. //***************************************************************************

  279. #define ANSI_MAYBE          0x0     // Device may or may not be ANSI approved stand

  280. #define ANSI_SCSI1          0x1     // Device complies to ANSI X3.131-1986 (SCSI-1)

  281. #define ANSI_SCSI2          0x2     // Device complies to SCSI-2

  282. #define ANSI_RESLO          0x3     // Reserved (low)

  283. #define ANSI_RESHI          0x7     // Reserved (high)

  284. 

  285. 

  286. typedef struct

  287. {

  288.   USHORT Length;

  289.   UCHAR  ScsiStatus;

  290.   UCHAR  PathId;

  291.   UCHAR  TargetId;

  292.   UCHAR  Lun;

  293.   UCHAR  CdbLength;

  294.   UCHAR  SenseInfoLength;

  295.   UCHAR  DataIn;

  296.   ULONG  DataTransferLength;

  297.   ULONG  TimeOutValue;

  298.   ULONG  DataBufferOffset;

  299.   ULONG  SenseInfoOffset;

  300.   UCHAR  Cdb[16];

  301. } SCSI_PASS_THROUGH, *PSCSI_PASS_THROUGH;

  302. 

  303. typedef struct

  304. {

  305.   USHORT Length;

  306.   UCHAR  ScsiStatus;

  307.   UCHAR  PathId;

  308.   UCHAR  TargetId;

  309.   UCHAR  Lun;

  310.   UCHAR  CdbLength;

  311.   UCHAR  SenseInfoLength;

  312.   UCHAR  DataIn;

  313.   ULONG  DataTransferLength;

  314.   ULONG  TimeOutValue;

  315.   PVOID  DataBuffer;

  316.   ULONG  SenseInfoOffset;

  317.   UCHAR  Cdb[16];

  318. } SCSI_PASS_THROUGH_DIRECT, *PSCSI_PASS_THROUGH_DIRECT;

  319. 

  320. typedef struct

  321. {

  322.   SCSI_PASS_THROUGH_DIRECT spt;

  323.   ULONG Filler;

  324.   UCHAR ucSenseBuf[32];

  325. } SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER, *PSCSI_PASS_THROUGH_DIRECT_WITH_BUFFER;

  326. 

  327. typedef struct

  328. {

  329.   ULONG Length;

  330.   UCHAR PortNumber;

  331.   UCHAR PathId;

  332.   UCHAR TargetId;

  333.   UCHAR Lun;

  334. } SCSI_ADDRESS, *PSCSI_ADDRESS;

  335. 

  336. 

  337. #define  METHOD_BUFFERED     0

  338. #define  METHOD_IN_DIRECT    1

  339. #define  METHOD_OUT_DIRECT   2

  340. #define  METHOD_NEITHER      3

  341. 

  342. #define  FILE_ANY_ACCESS      0

  343. #ifndef FILE_READ_ACCESS

  344. #define  FILE_READ_ACCESS     (0x0001)

  345. #endif

  346. #ifndef FILE_WRITE_ACCESS

  347. #define  FILE_WRITE_ACCESS    (0x0002)

  348. #endif

  349. 

  350. #define IOCTL_SCSI_BASE    0x00000004

  351. 

  352. #define  SCSI_IOCTL_DATA_OUT          0

  353. #define  SCSI_IOCTL_DATA_IN           1

  354. #define  SCSI_IOCTL_DATA_UNSPECIFIED  2

  355. 

  356. #define CTL_CODE2( DevType, Function, Method, Access ) (                 \

  357.     ((DevType) << 16) | ((Access) << 14) | ((Function) << 2) | (Method) \

  358. )

  359. 

  360. #define IOCTL_SCSI_PASS_THROUGH         CTL_CODE2( IOCTL_SCSI_BASE, 0x0401, METHOD_BUFFERED, FILE_READ_ACCESS | FILE_WRITE_ACCESS )

  361. #define IOCTL_SCSI_GET_CAPABILITIES     CTL_CODE2( IOCTL_SCSI_BASE, 0x0404, METHOD_BUFFERED, FILE_ANY_ACCESS)

  362. #define IOCTL_SCSI_PASS_THROUGH_DIRECT  CTL_CODE2( IOCTL_SCSI_BASE, 0x0405, METHOD_BUFFERED, FILE_READ_ACCESS | FILE_WRITE_ACCESS )

  363. #define IOCTL_SCSI_GET_ADDRESS          CTL_CODE2( IOCTL_SCSI_BASE, 0x0406, METHOD_BUFFERED, FILE_ANY_ACCESS )

  364. 

  365. 

  366. #define SENSE_LEN                 14

  367. #define SRB_DIR_SCSI              0x00

  368. #define SRB_POSTING               0x01

  369. #define SRB_ENABLE_RESIDUAL_COUNT 0x04

  370. #define SRB_DIR_IN                0x08

  371. #define SRB_DIR_OUT               0x10

  372. #define SRB_EVENT_NOTIFY          0x40

  373. #define RESIDUAL_COUNT_SUPPORTED  0x02

  374. #define MAX_SRB_TIMEOUT       1080001u

  375. #define DEFAULT_SRB_TIMEOUT   1080001u

  376. 

  377. #define SC_HA_INQUIRY             0x00

  378. #define SC_GET_DEV_TYPE           0x01

  379. #define SC_EXEC_SCSI_CMD          0x02

  380. #define SC_ABORT_SRB              0x03

  381. #define SC_RESET_DEV              0x04

  382. #define SC_SET_HA_PARMS           0x05

  383. #define SC_GET_DISK_INFO          0x06

  384. #define SC_RESCAN_SCSI_BUS        0x07

  385. #define SC_GETSET_TIMEOUTS        0x08

  386. 

  387. #define SS_PENDING                0x00

  388. #define SS_COMP                   0x01

  389. #define SS_ABORTED                0x02

  390. #define SS_ABORT_FAIL             0x03

  391. #define SS_ERR                    0x04

  392. #define SS_INVALID_CMD            0x80

  393. #define SS_INVALID_HA             0x81

  394. #define SS_NO_DEVICE              0x82

  395. #define SS_INVALID_SRB            0xE0

  396. #define SS_OLD_MANAGER            0xE1

  397. #define SS_BUFFER_ALIGN           0xE1

  398. #define SS_ILLEGAL_MODE           0xE2

  399. #define SS_NO_ASPI                0xE3

  400. #define SS_FAILED_INIT            0xE4

  401. #define SS_ASPI_IS_BUSY           0xE5

  402. #define SS_BUFFER_TO_BIG          0xE6

  403. #define SS_BUFFER_TOO_BIG         0xE6

  404. #define SS_MISMATCHED_COMPONENTS  0xE7

  405. #define SS_NO_ADAPTERS            0xE8

  406. #define SS_INSUFFICIENT_RESOURCES 0xE9

  407. #define SS_ASPI_IS_SHUTDOWN       0xEA

  408. #define SS_BAD_INSTALL            0xEB

  409. 

  410. #define HASTAT_OK                 0x00

  411. #define HASTAT_SEL_TO             0x11

  412. #define HASTAT_DO_DU              0x12

  413. #define HASTAT_BUS_FREE           0x13

  414. #define HASTAT_PHASE_ERR          0x14

  415. #define HASTAT_TIMEOUT            0x09

  416. #define HASTAT_COMMAND_TIMEOUT    0x0B

  417. #define HASTAT_MESSAGE_REJECT     0x0D

  418. #define HASTAT_BUS_RESET          0x0E

  419. #define HASTAT_PARITY_ERROR       0x0F

  420. #define HASTAT_REQUEST_SENSE_FAILED 0x10

  421. 

  422. #define PACKED

  423. #pragma pack(1)

  424. 

  425. typedef struct

  426. {

  427.   BYTE     SRB_Cmd;

  428.   BYTE     SRB_Status;

  429.   BYTE     SRB_HaID;

  430.   BYTE     SRB_Flags;

  431.   DWORD    SRB_Hdr_Rsvd;

  432.   BYTE     HA_Count;

  433.   BYTE     HA_SCSI_ID;

  434.   BYTE     HA_ManagerId[16];

  435.   BYTE     HA_Identifier[16];

  436.   BYTE     HA_Unique[16];

  437.   WORD     HA_Rsvd1;

  438.   BYTE     pad[20];

  439. } PACKED SRB_HAInquiry, *PSRB_HAInquiry, FAR *LPSRB_HAInquiry;

  440. 

  441. 

  442. typedef struct

  443. {

  444.   BYTE     SRB_Cmd;

  445.   BYTE     SRB_Status;

  446.   BYTE     SRB_HaID;

  447.   BYTE     SRB_Flags;

  448.   DWORD    SRB_Hdr_Rsvd;

  449.   BYTE     SRB_Target;

  450.   BYTE     SRB_Lun;

  451.   BYTE     SRB_DeviceType;

  452.   BYTE     SRB_Rsvd1;

  453.   BYTE     pad[68];

  454. } PACKED SRB_GDEVBlock, *PSRB_GDEVBlock, FAR *LPSRB_GDEVBlock;

  455. 

  456. 

  457. typedef struct

  458. {

  459.   BYTE     SRB_Cmd;

  460.   BYTE     SRB_Status;

  461.   BYTE     SRB_HaID;

  462.   BYTE     SRB_Flags;

  463.   DWORD    SRB_Hdr_Rsvd;

  464.   BYTE     SRB_Target;

  465.   BYTE     SRB_Lun;

  466.   WORD     SRB_Rsvd1;

  467.   DWORD    SRB_BufLen;

  468.   BYTE FAR *SRB_BufPointer;

  469.   BYTE     SRB_SenseLen;

  470.   BYTE     SRB_CDBLen;

  471.   BYTE     SRB_HaStat;

  472.   BYTE     SRB_TargStat;

  473.   VOID FAR *SRB_PostProc;

  474.   BYTE     SRB_Rsvd2[20];

  475.   BYTE     CDBByte[16];

  476.   BYTE SenseArea[SENSE_LEN+2];

  477. } PACKED SRB_ExecSCSICmd, *PSRB_ExecSCSICmd, FAR *LPSRB_ExecSCSICmd;

  478. 

  479. 

  480. typedef struct

  481. {

  482.   BYTE      SRB_Cmd;

  483.   BYTE      SRB_Status;

  484.   BYTE      SRB_HaId;

  485.   BYTE      SRB_Flags;

  486.   DWORD     SRB_Hdr_Rsvd;

  487. } PACKED SRB, *PSRB, FAR *LPSRB;

  488. 

  489. #pragma pack()

  490. 

  491. 

  492. //==============================================================================

  493. struct CDDeviceInfo

  494. {

  495.     char vendor[9];

  496.     char productId[17];

  497.     char rev[5];

  498.     char vendorSpec[21];

  499. 

  500.     BYTE ha;

  501.     BYTE tgt;

  502.     BYTE lun;

  503.     char scsiDriveLetter; // will be 0 if not using scsi

  504. };

  505. 

  506. 

  507. //==============================================================================

  508. class CDReadBuffer

  509. {

  510. public:

  511.     int startFrame;

  512.     int numFrames;

  513.     int dataStartOffset;

  514.     int dataLength;

  515.     BYTE* buffer;

  516.     int bufferSize;

  517.     int index;

  518.     bool wantsIndex;

  519. 

  520.     //==============================================================================

  521.     CDReadBuffer (const int numberOfFrames)

  522.         : startFrame (0),

  523.           numFrames (0),

  524.           dataStartOffset (0),

  525.           dataLength (0),

  526.           index (0),

  527.           wantsIndex (false)

  528.     {

  529.         bufferSize = 2352 * numberOfFrames;

  530.         buffer = (BYTE*) malloc (bufferSize);

  531.     }

  532. 

  533.     ~CDReadBuffer()

  534.     {

  535.         free (buffer);

  536.     }

  537. 

  538.     bool isZero() const

  539.     {

  540.         BYTE* p = buffer + dataStartOffset;

  541. 

  542.         for (int i = dataLength; --i >= 0;)

  543.             if (*p++ != 0)

  544.                 return false;

  545. 

  546.         return true;

  547.     }

  548. };

  549. 

  550. class CDDeviceHandle;

  551. 

  552. class CDController

  553. {

  554. public:

  555.     CDController();

  556.     virtual ~CDController();

  557. 

  558.     virtual bool read (CDReadBuffer* t) = 0;

  559.     virtual void shutDown();

  560. 

  561.     bool readAudio (CDReadBuffer* t, CDReadBuffer* overlapBuffer = 0);

  562.     int getLastIndex();

  563. 

  564. public:

  565.     bool initialised;

  566. 

  567.     CDDeviceHandle* deviceInfo;

  568.     int framesToCheck, framesOverlap;

  569. 

  570.     void prepare (SRB_ExecSCSICmd& s);

  571.     void perform (SRB_ExecSCSICmd& s);

  572.     void setPaused (bool paused);

  573. };

  574. 

  575. 

  576. //==============================================================================

  577. #pragma pack(1)

  578. 

  579. struct TOCTRACK

  580. {

  581.     BYTE rsvd;

  582.     BYTE ADR;

  583.     BYTE trackNumber;

  584.     BYTE rsvd2;

  585.     BYTE addr[4];

  586. };

  587. 

  588. struct TOC

  589. {

  590.     WORD tocLen;

  591.     BYTE firstTrack;

  592.     BYTE lastTrack;

  593.     TOCTRACK tracks[100];

  594. };

  595. 

  596. #pragma pack()

  597. 

  598. enum

  599. {

  600.     READTYPE_ANY = 0,

  601.     READTYPE_ATAPI1 = 1,

  602.     READTYPE_ATAPI2 = 2,

  603.     READTYPE_READ6 = 3,

  604.     READTYPE_READ10 = 4,

  605.     READTYPE_READ_D8 = 5,

  606.     READTYPE_READ_D4 = 6,

  607.     READTYPE_READ_D4_1 = 7,

  608.     READTYPE_READ10_2 = 8

  609. };

  610. 

  611. 

  612. //==============================================================================

  613. class CDDeviceHandle

  614. {

  615. public:

  616.     CDDeviceHandle (const CDDeviceInfo* const device)

  617.         : scsiHandle (0),

  618.           readType (READTYPE_ANY),

  619.           controller (0)

  620.     {

  621.         memcpy (&info, device, sizeof (info));

  622.     }

  623. 

  624.     ~CDDeviceHandle()

  625.     {

  626.         if (controller != 0)

  627.         {

  628.             controller->shutDown();

  629.             delete controller;

  630.         }

  631. 

  632.         if (scsiHandle != 0)

  633.             CloseHandle (scsiHandle);

  634.     }

  635. 

  636.     bool readTOC (TOC* lpToc, bool useMSF);

  637.     bool readAudio (CDReadBuffer* buffer, CDReadBuffer* overlapBuffer = 0);

  638.     void openDrawer (bool shouldBeOpen);

  639. 

  640.     CDDeviceInfo info;

  641.     HANDLE scsiHandle;

  642.     BYTE readType;

  643. 

  644. private:

  645.     CDController* controller;

  646. 

  647.     bool testController (const int readType,

  648.                          CDController* const newController,

  649.                          CDReadBuffer* const bufferToUse);

  650. };

  651. 

  652. 

  653. //==============================================================================

  654. DWORD (*fGetASPI32SupportInfo)(void);

  655. DWORD (*fSendASPI32Command)(LPSRB);

  656. 

  657. //==============================================================================

  658. static HINSTANCE winAspiLib = 0;

  659. static bool usingScsi = false;

  660. static bool initialised = false;

  661. 

  662. 

  663. static bool InitialiseCDRipper()

  664. {

  665.     if (! initialised)

  666.     {

  667.         initialised = true;

  668. 

  669.         OSVERSIONINFO info;

  670.         info.dwOSVersionInfoSize = sizeof (info);

  671.         GetVersionEx (&info);

  672. 

  673.         usingScsi = (info.dwPlatformId == VER_PLATFORM_WIN32_NT) && (info.dwMajorVersion > 4);

  674. 

  675.         if (! usingScsi)

  676.         {

  677.             fGetASPI32SupportInfo = 0;

  678.             fSendASPI32Command = 0;

  679.             winAspiLib = LoadLibrary (_T("WNASPI32.DLL"));

  680. 

  681.             if (winAspiLib != 0)

  682.             {

  683.                 fGetASPI32SupportInfo = (DWORD(*)(void))  GetProcAddress (winAspiLib, "GetASPI32SupportInfo");

  684.                 fSendASPI32Command    = (DWORD(*)(LPSRB)) GetProcAddress (winAspiLib, "SendASPI32Command");

  685. 

  686.                 if (fGetASPI32SupportInfo == 0 || fSendASPI32Command == 0)

  687.                     return false;

  688.             }

  689.             else

  690.             {

  691.                 usingScsi = true;

  692.             }

  693.         }

  694.     }

  695. 

  696.     return true;

  697. }

  698. 

  699. static void DeinitialiseCDRipper()

  700. {

  701.     if (winAspiLib != 0)

  702.     {

  703.         fGetASPI32SupportInfo = 0;

  704.         fSendASPI32Command = 0;

  705.         FreeLibrary (winAspiLib);

  706.         winAspiLib = 0;

  707.     }

  708. 

  709.     initialised = false;

  710. }

  711. 

  712. //==============================================================================

  713. static HANDLE CreateSCSIDeviceHandle (char driveLetter)

  714. {

  715.     TCHAR devicePath[8];

  716.     devicePath[0] = '\\';

  717.     devicePath[1] = '\\';

  718.     devicePath[2] = '.';

  719.     devicePath[3] = '\\';

  720.     devicePath[4] = driveLetter;

  721.     devicePath[5] = ':';

  722.     devicePath[6] = 0;

  723. 

  724.     OSVERSIONINFO info;

  725.     info.dwOSVersionInfoSize = sizeof (info);

  726.     GetVersionEx (&info);

  727. 

  728.     DWORD flags = GENERIC_READ;

  729. 

  730.     if ((info.dwPlatformId == VER_PLATFORM_WIN32_NT) && (info.dwMajorVersion > 4))

  731.         flags = GENERIC_READ | GENERIC_WRITE;

  732. 

  733.     HANDLE h = CreateFile (devicePath, flags, FILE_SHARE_WRITE | FILE_SHARE_READ, 0, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, 0);

  734. 

  735.     if (h == INVALID_HANDLE_VALUE)

  736.     {

  737.         flags ^= GENERIC_WRITE;

  738.         h = CreateFile (devicePath, flags, FILE_SHARE_WRITE | FILE_SHARE_READ, 0, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, 0);

  739.     }

  740. 

  741.     return h;

  742. }

  743. 

  744. static DWORD performScsiPassThroughCommand (const LPSRB_ExecSCSICmd srb,

  745.                                             const char driveLetter,

  746.                                             HANDLE& deviceHandle,

  747.                                             const bool retryOnFailure = true)

  748. {

  749.     SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER s;

  750.     zerostruct (s);

  751. 

  752.     s.spt.Length = sizeof (SCSI_PASS_THROUGH);

  753.     s.spt.CdbLength = srb->SRB_CDBLen;

  754. 

  755.     s.spt.DataIn = (BYTE) ((srb->SRB_Flags & SRB_DIR_IN)

  756.                             ? SCSI_IOCTL_DATA_IN

  757.                             : ((srb->SRB_Flags & SRB_DIR_OUT)

  758.                                 ? SCSI_IOCTL_DATA_OUT

  759.                                 : SCSI_IOCTL_DATA_UNSPECIFIED));

  760. 

  761.     s.spt.DataTransferLength = srb->SRB_BufLen;

  762.     s.spt.TimeOutValue = 5;

  763.     s.spt.DataBuffer = srb->SRB_BufPointer;

  764.     s.spt.SenseInfoOffset = offsetof (SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER, ucSenseBuf);

  765. 

  766.     memcpy (s.spt.Cdb, srb->CDBByte, srb->SRB_CDBLen);

  767. 

  768.     srb->SRB_Status = SS_ERR;

  769.     srb->SRB_TargStat = 0x0004;

  770. 

  771.     DWORD bytesReturned = 0;

  772. 

  773.     if (DeviceIoControl (deviceHandle, IOCTL_SCSI_PASS_THROUGH_DIRECT,

  774.                          &s, sizeof (s),

  775.                          &s, sizeof (s),

  776.                          &bytesReturned, 0) != 0)

  777.     {

  778.         srb->SRB_Status = SS_COMP;

  779.     }

  780.     else if (retryOnFailure)

  781.     {

  782.         const DWORD error = GetLastError();

  783. 

  784.         if ((error == ERROR_MEDIA_CHANGED) || (error == ERROR_INVALID_HANDLE))

  785.         {

  786.             if (error != ERROR_INVALID_HANDLE)

  787.                 CloseHandle (deviceHandle);

  788. 

  789.             deviceHandle = CreateSCSIDeviceHandle (driveLetter);

  790. 

  791.             return performScsiPassThroughCommand (srb, driveLetter, deviceHandle, false);

  792.         }

  793.     }

  794. 

  795.     return srb->SRB_Status;

  796. }

  797. 

  798. 

  799. //==============================================================================

  800. // Controller types..

  801. 

  802. class ControllerType1  : public CDController

  803. {

  804. public:

  805.     ControllerType1() {}

  806.     ~ControllerType1() {}

  807. 

  808.     bool read (CDReadBuffer* rb)

  809.     {

  810.         if (rb->numFrames * 2352 > rb->bufferSize)

  811.             return false;

  812. 

  813.         SRB_ExecSCSICmd s;

  814.         prepare (s);

  815.         s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  816.         s.SRB_BufLen = rb->bufferSize;

  817.         s.SRB_BufPointer = rb->buffer;

  818.         s.SRB_CDBLen = 12;

  819.         s.CDBByte[0] = 0xBE;

  820.         s.CDBByte[3] = (BYTE)((rb->startFrame >> 16) & 0xFF);

  821.         s.CDBByte[4] = (BYTE)((rb->startFrame >> 8) & 0xFF);

  822.         s.CDBByte[5] = (BYTE)(rb->startFrame & 0xFF);

  823.         s.CDBByte[8] = (BYTE)(rb->numFrames & 0xFF);

  824.         s.CDBByte[9] = (BYTE)((deviceInfo->readType == READTYPE_ATAPI1) ? 0x10 : 0xF0);

  825.         perform (s);

  826. 

  827.         if (s.SRB_Status != SS_COMP)

  828.             return false;

  829. 

  830.         rb->dataLength = rb->numFrames * 2352;

  831.         rb->dataStartOffset = 0;

  832.         return true;

  833.     }

  834. };

  835. 

  836. 

  837. //==============================================================================

  838. class ControllerType2  : public CDController

  839. {

  840. public:

  841.     ControllerType2() {}

  842.     ~ControllerType2() {}

  843. 

  844.     void shutDown()

  845.     {

  846.         if (initialised)

  847.         {

  848.             BYTE bufPointer[] = { 0, 0, 0, 8, 83, 0, 0, 0, 0, 0, 8, 0 };

  849. 

  850.             SRB_ExecSCSICmd s;

  851.             prepare (s);

  852.             s.SRB_Flags = SRB_EVENT_NOTIFY | SRB_ENABLE_RESIDUAL_COUNT;

  853.             s.SRB_BufLen = 0x0C;

  854.             s.SRB_BufPointer = bufPointer;

  855.             s.SRB_CDBLen = 6;

  856.             s.CDBByte[0] = 0x15;

  857.             s.CDBByte[4] = 0x0C;

  858.             perform (s);

  859.         }

  860.     }

  861. 

  862.     bool init()

  863.     {

  864.         SRB_ExecSCSICmd s;

  865.         s.SRB_Status = SS_ERR;

  866. 

  867.         if (deviceInfo->readType == READTYPE_READ10_2)

  868.         {

  869.             BYTE bufPointer1[] = { 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 9, 48, 35, 6, 0, 0, 0, 0, 0, 128 };

  870.             BYTE bufPointer2[] = { 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 9, 48, 1, 6, 32, 7, 0, 0, 0, 0 };

  871. 

  872.             for (int i = 0; i < 2; ++i)

  873.             {

  874.                 prepare (s);

  875.                 s.SRB_Flags = SRB_EVENT_NOTIFY;

  876.                 s.SRB_BufLen = 0x14;

  877.                 s.SRB_BufPointer = (i == 0) ? bufPointer1 : bufPointer2;

  878.                 s.SRB_CDBLen = 6;

  879.                 s.CDBByte[0] = 0x15;

  880.                 s.CDBByte[1] = 0x10;

  881.                 s.CDBByte[4] = 0x14;

  882.                 perform (s);

  883. 

  884.                 if (s.SRB_Status != SS_COMP)

  885.                     return false;

  886.             }

  887.         }

  888.         else

  889.         {

  890.             BYTE bufPointer[] = { 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 9, 48 };

  891. 

  892.             prepare (s);

  893.             s.SRB_Flags = SRB_EVENT_NOTIFY;

  894.             s.SRB_BufLen = 0x0C;

  895.             s.SRB_BufPointer = bufPointer;

  896.             s.SRB_CDBLen = 6;

  897.             s.CDBByte[0] = 0x15;

  898.             s.CDBByte[4] = 0x0C;

  899.             perform (s);

  900.         }

  901. 

  902.         return s.SRB_Status == SS_COMP;

  903.     }

  904. 

  905.     bool read (CDReadBuffer* rb)

  906.     {

  907.         if (rb->numFrames * 2352 > rb->bufferSize)

  908.             return false;

  909. 

  910.         if (!initialised)

  911.         {

  912.             initialised = init();

  913. 

  914.             if (!initialised)

  915.                 return false;

  916.         }

  917. 

  918.         SRB_ExecSCSICmd s;

  919.         prepare (s);

  920.         s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  921.         s.SRB_BufLen = rb->bufferSize;

  922.         s.SRB_BufPointer = rb->buffer;

  923.         s.SRB_CDBLen = 10;

  924.         s.CDBByte[0] = 0x28;

  925.         s.CDBByte[1] = (BYTE)(deviceInfo->info.lun << 5);

  926.         s.CDBByte[3] = (BYTE)((rb->startFrame >> 16) & 0xFF);

  927.         s.CDBByte[4] = (BYTE)((rb->startFrame >> 8) & 0xFF);

  928.         s.CDBByte[5] = (BYTE)(rb->startFrame & 0xFF);

  929.         s.CDBByte[8] = (BYTE)(rb->numFrames & 0xFF);

  930.         perform (s);

  931. 

  932.         if (s.SRB_Status != SS_COMP)

  933.             return false;

  934. 

  935.         rb->dataLength = rb->numFrames * 2352;

  936.         rb->dataStartOffset = 0;

  937. 

  938.         return true;

  939.     }

  940. };

  941. 

  942. 

  943. //==============================================================================

  944. class ControllerType3  : public CDController

  945. {

  946. public:

  947.     ControllerType3() {}

  948.     ~ControllerType3() {}

  949. 

  950.     bool read (CDReadBuffer* rb)

  951.     {

  952.         if (rb->numFrames * 2352 > rb->bufferSize)

  953.             return false;

  954. 

  955.         if (!initialised)

  956.         {

  957.             setPaused (false);

  958.             initialised = true;

  959.         }

  960. 

  961.         SRB_ExecSCSICmd s;

  962.         prepare (s);

  963.         s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  964.         s.SRB_BufLen = rb->numFrames * 2352;

  965.         s.SRB_BufPointer = rb->buffer;

  966.         s.SRB_CDBLen = 12;

  967.         s.CDBByte[0] = 0xD8;

  968.         s.CDBByte[3] = (BYTE)((rb->startFrame >> 16) & 0xFF);

  969.         s.CDBByte[4] = (BYTE)((rb->startFrame >> 8) & 0xFF);

  970.         s.CDBByte[5] = (BYTE)(rb->startFrame & 0xFF);

  971.         s.CDBByte[9] = (BYTE)(rb->numFrames & 0xFF);

  972.         perform (s);

  973. 

  974.         if (s.SRB_Status != SS_COMP)

  975.             return false;

  976. 

  977.         rb->dataLength = rb->numFrames * 2352;

  978.         rb->dataStartOffset = 0;

  979. 

  980.         return true;

  981.     }

  982. };

  983. 

  984. 

  985. //==============================================================================

  986. class ControllerType4  : public CDController

  987. {

  988. public:

  989.     ControllerType4() {}

  990.     ~ControllerType4() {}

  991. 

  992.     bool selectD4Mode()

  993.     {

  994.         BYTE bufPointer[12] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 9, 48 };

  995. 

  996.         SRB_ExecSCSICmd s;

  997.         prepare (s);

  998.         s.SRB_Flags = SRB_EVENT_NOTIFY;

  999.         s.SRB_CDBLen = 6;

  1000.         s.SRB_BufLen = 12;

  1001.         s.SRB_BufPointer = bufPointer;

  1002.         s.CDBByte[0] = 0x15;

  1003.         s.CDBByte[1] = 0x10;

  1004.         s.CDBByte[4] = 0x08;

  1005.         perform (s);

  1006. 

  1007.         return s.SRB_Status == SS_COMP;

  1008.     }

  1009. 

  1010.     bool read (CDReadBuffer* rb)

  1011.     {

  1012.         if (rb->numFrames * 2352 > rb->bufferSize)

  1013.             return false;

  1014. 

  1015.         if (!initialised)

  1016.         {

  1017.             setPaused (true);

  1018. 

  1019.             if (deviceInfo->readType == READTYPE_READ_D4_1)

  1020.                 selectD4Mode();

  1021. 

  1022.             initialised = true;

  1023.         }

  1024. 

  1025.         SRB_ExecSCSICmd s;

  1026.         prepare (s);

  1027.         s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  1028.         s.SRB_BufLen = rb->bufferSize;

  1029.         s.SRB_BufPointer = rb->buffer;

  1030.         s.SRB_CDBLen = 10;

  1031.         s.CDBByte[0] = 0xD4;

  1032.         s.CDBByte[3] = (BYTE)((rb->startFrame >> 16) & 0xFF);

  1033.         s.CDBByte[4] = (BYTE)((rb->startFrame >> 8) & 0xFF);

  1034.         s.CDBByte[5] = (BYTE)(rb->startFrame & 0xFF);

  1035.         s.CDBByte[8] = (BYTE)(rb->numFrames & 0xFF);

  1036.         perform (s);

  1037. 

  1038.         if (s.SRB_Status != SS_COMP)

  1039.             return false;

  1040. 

  1041.         rb->dataLength = rb->numFrames * 2352;

  1042.         rb->dataStartOffset = 0;

  1043. 

  1044.         return true;

  1045.     }

  1046. };

  1047. 

  1048. 

  1049. //==============================================================================

  1050. CDController::CDController()  : initialised (false)

  1051. {

  1052. }

  1053. 

  1054. CDController::~CDController()

  1055. {

  1056. }

  1057. 

  1058. void CDController::prepare (SRB_ExecSCSICmd& s)

  1059. {

  1060.     zerostruct (s);

  1061. 

  1062.     s.SRB_Cmd = SC_EXEC_SCSI_CMD;

  1063.     s.SRB_HaID = deviceInfo->info.ha;

  1064.     s.SRB_Target = deviceInfo->info.tgt;

  1065.     s.SRB_Lun = deviceInfo->info.lun;

  1066.     s.SRB_SenseLen = SENSE_LEN;

  1067. }

  1068. 

  1069. void CDController::perform (SRB_ExecSCSICmd& s)

  1070. {

  1071.     HANDLE event = CreateEvent (0, TRUE, FALSE, 0);

  1072.     s.SRB_PostProc = (void*)event;

  1073. 

  1074.     ResetEvent (event);

  1075. 

  1076.     DWORD status = (usingScsi) ? performScsiPassThroughCommand ((LPSRB_ExecSCSICmd)&s,

  1077.                                                                 deviceInfo->info.scsiDriveLetter,

  1078.                                                                 deviceInfo->scsiHandle)

  1079.                                : fSendASPI32Command ((LPSRB)&s);

  1080. 

  1081.     if (status == SS_PENDING)

  1082.         WaitForSingleObject (event, 4000);

  1083. 

  1084.     CloseHandle (event);

  1085. }

  1086. 

  1087. void CDController::setPaused (bool paused)

  1088. {

  1089.     SRB_ExecSCSICmd s;

  1090.     prepare (s);

  1091.     s.SRB_Flags = SRB_EVENT_NOTIFY;

  1092.     s.SRB_CDBLen = 10;

  1093.     s.CDBByte[0] = 0x4B;

  1094.     s.CDBByte[8] = (BYTE) (paused ? 0 : 1);

  1095.     perform (s);

  1096. }

  1097. 

  1098. void CDController::shutDown()

  1099. {

  1100. }

  1101. 

  1102. bool CDController::readAudio (CDReadBuffer* rb, CDReadBuffer* overlapBuffer)

  1103. {

  1104.     if (overlapBuffer != 0)

  1105.     {

  1106.         const bool canDoJitter = (overlapBuffer->bufferSize >= 2352 * framesToCheck);

  1107.         const bool doJitter = canDoJitter && ! overlapBuffer->isZero();

  1108. 

  1109.         if (doJitter

  1110.              && overlapBuffer->startFrame > 0

  1111.              && overlapBuffer->numFrames > 0

  1112.              && overlapBuffer->dataLength > 0)

  1113.         {

  1114.             const int numFrames = rb->numFrames;

  1115. 

  1116.             if (overlapBuffer->startFrame == (rb->startFrame - framesToCheck))

  1117.             {

  1118.                 rb->startFrame -= framesOverlap;

  1119. 

  1120.                 if (framesToCheck < framesOverlap

  1121.                      && numFrames + framesOverlap <= rb->bufferSize / 2352)

  1122.                     rb->numFrames += framesOverlap;

  1123.             }

  1124.             else

  1125.             {

  1126.                 overlapBuffer->dataLength = 0;

  1127.                 overlapBuffer->startFrame = 0;

  1128.                 overlapBuffer->numFrames = 0;

  1129.             }

  1130.         }

  1131. 

  1132.         if (! read (rb))

  1133.             return false;

  1134. 

  1135.         if (doJitter)

  1136.         {

  1137.             const int checkLen = framesToCheck * 2352;

  1138.             const int maxToCheck = rb->dataLength - checkLen;

  1139. 

  1140.             if (overlapBuffer->dataLength == 0 || overlapBuffer->isZero())

  1141.                 return true;

  1142. 

  1143.             BYTE* const p = overlapBuffer->buffer + overlapBuffer->dataStartOffset;

  1144.             bool found = false;

  1145. 

  1146.             for (int i = 0; i < maxToCheck; ++i)

  1147.             {

  1148.                 if (!memcmp (p, rb->buffer + i, checkLen))

  1149.                 {

  1150.                     i += checkLen;

  1151.                     rb->dataStartOffset = i;

  1152.                     rb->dataLength -= i;

  1153.                     rb->startFrame = overlapBuffer->startFrame + framesToCheck;

  1154.                     found = true;

  1155.                     break;

  1156.                 }

  1157.             }

  1158. 

  1159.             rb->numFrames = rb->dataLength / 2352;

  1160.             rb->dataLength = 2352 * rb->numFrames;

  1161. 

  1162.             if (!found)

  1163.                 return false;

  1164.         }

  1165. 

  1166.         if (canDoJitter)

  1167.         {

  1168.             memcpy (overlapBuffer->buffer,

  1169.                     rb->buffer + rb->dataStartOffset + 2352 * (rb->numFrames - framesToCheck),

  1170.                     2352 * framesToCheck);

  1171. 

  1172.             overlapBuffer->startFrame = rb->startFrame + rb->numFrames - framesToCheck;

  1173.             overlapBuffer->numFrames = framesToCheck;

  1174.             overlapBuffer->dataLength = 2352 * framesToCheck;

  1175.             overlapBuffer->dataStartOffset = 0;

  1176.         }

  1177.         else

  1178.         {

  1179.             overlapBuffer->startFrame = 0;

  1180.             overlapBuffer->numFrames = 0;

  1181.             overlapBuffer->dataLength = 0;

  1182.         }

  1183. 

  1184.         return true;

  1185.     }

  1186.     else

  1187.     {

  1188.         return read (rb);

  1189.     }

  1190. }

  1191. 

  1192. int CDController::getLastIndex()

  1193. {

  1194.     char qdata[100];

  1195. 

  1196.     SRB_ExecSCSICmd s;

  1197.     prepare (s);

  1198.     s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  1199.     s.SRB_BufLen = sizeof (qdata);

  1200.     s.SRB_BufPointer = (BYTE*)qdata;

  1201.     s.SRB_CDBLen = 12;

  1202.     s.CDBByte[0] = 0x42;

  1203.     s.CDBByte[1] = (BYTE)(deviceInfo->info.lun << 5);

  1204.     s.CDBByte[2] = 64;

  1205.     s.CDBByte[3] = 1; // get current position

  1206.     s.CDBByte[7] = 0;

  1207.     s.CDBByte[8] = (BYTE)sizeof (qdata);

  1208.     perform (s);

  1209. 

  1210.     if (s.SRB_Status == SS_COMP)

  1211.         return qdata[7];

  1212. 

  1213.     return 0;

  1214. }

  1215. 

  1216. //==============================================================================

  1217. bool CDDeviceHandle::readTOC (TOC* lpToc, bool useMSF)

  1218. {

  1219.     HANDLE event = CreateEvent (0, TRUE, FALSE, 0);

  1220. 

  1221.     SRB_ExecSCSICmd s;

  1222.     zerostruct (s);

  1223. 

  1224.     s.SRB_Cmd = SC_EXEC_SCSI_CMD;

  1225.     s.SRB_HaID = info.ha;

  1226.     s.SRB_Target = info.tgt;

  1227.     s.SRB_Lun = info.lun;

  1228.     s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  1229.     s.SRB_BufLen = 0x324;

  1230.     s.SRB_BufPointer = (BYTE*)lpToc;

  1231.     s.SRB_SenseLen = 0x0E;

  1232.     s.SRB_CDBLen = 0x0A;

  1233.     s.SRB_PostProc = (void*)event;

  1234.     s.CDBByte[0] = 0x43;

  1235.     s.CDBByte[1] = (BYTE)(useMSF ? 0x02 : 0x00);

  1236.     s.CDBByte[7] = 0x03;

  1237.     s.CDBByte[8] = 0x24;

  1238. 

  1239.     ResetEvent (event);

  1240.     DWORD status = (usingScsi) ? performScsiPassThroughCommand ((LPSRB_ExecSCSICmd)&s, info.scsiDriveLetter, scsiHandle)

  1241.                                : fSendASPI32Command ((LPSRB)&s);

  1242. 

  1243.     if (status == SS_PENDING)

  1244.         WaitForSingleObject (event, 4000);

  1245. 

  1246.     CloseHandle (event);

  1247.     return (s.SRB_Status == SS_COMP);

  1248. }

  1249. 

  1250. bool CDDeviceHandle::readAudio (CDReadBuffer* const buffer,

  1251.                                 CDReadBuffer* const overlapBuffer)

  1252. {

  1253.     if (controller == 0)

  1254.     {

  1255.            testController (READTYPE_ATAPI2,    new ControllerType1(), buffer)

  1256.         || testController (READTYPE_ATAPI1,    new ControllerType1(), buffer)

  1257.         || testController (READTYPE_READ10_2,  new ControllerType2(), buffer)

  1258.         || testController (READTYPE_READ10,    new ControllerType2(), buffer)

  1259.         || testController (READTYPE_READ_D8,   new ControllerType3(), buffer)

  1260.         || testController (READTYPE_READ_D4,   new ControllerType4(), buffer)

  1261.         || testController (READTYPE_READ_D4_1, new ControllerType4(), buffer);

  1262.     }

  1263. 

  1264.     buffer->index = 0;

  1265. 

  1266.     if ((controller != 0)

  1267.         && controller->readAudio (buffer, overlapBuffer))

  1268.     {

  1269.         if (buffer->wantsIndex)

  1270.             buffer->index = controller->getLastIndex();

  1271. 

  1272.         return true;

  1273.     }

  1274. 

  1275.     return false;

  1276. }

  1277. 

  1278. void CDDeviceHandle::openDrawer (bool shouldBeOpen)

  1279. {

  1280.     if (shouldBeOpen)

  1281.     {

  1282.         if (controller != 0)

  1283.         {

  1284.             controller->shutDown();

  1285.             delete controller;

  1286.             controller = 0;

  1287.         }

  1288. 

  1289.         if (scsiHandle != 0)

  1290.         {

  1291.             CloseHandle (scsiHandle);

  1292.             scsiHandle = 0;

  1293.         }

  1294.     }

  1295. 

  1296.     SRB_ExecSCSICmd s;

  1297.     zerostruct (s);

  1298. 

  1299.     s.SRB_Cmd = SC_EXEC_SCSI_CMD;

  1300.     s.SRB_HaID = info.ha;

  1301.     s.SRB_Target = info.tgt;

  1302.     s.SRB_Lun = info.lun;

  1303.     s.SRB_SenseLen = SENSE_LEN;

  1304.     s.SRB_Flags = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  1305.     s.SRB_BufLen = 0;

  1306.     s.SRB_BufPointer = 0;

  1307.     s.SRB_CDBLen = 12;

  1308.     s.CDBByte[0] = 0x1b;

  1309.     s.CDBByte[1] = (BYTE)(info.lun << 5);

  1310.     s.CDBByte[4] = (BYTE)((shouldBeOpen) ? 2 : 3);

  1311. 

  1312.     HANDLE event = CreateEvent (0, TRUE, FALSE, 0);

  1313.     s.SRB_PostProc = (void*)event;

  1314. 

  1315.     ResetEvent (event);

  1316. 

  1317.     DWORD status = (usingScsi) ? performScsiPassThroughCommand  ((LPSRB_ExecSCSICmd)&s, info.scsiDriveLetter, scsiHandle)

  1318.                                : fSendASPI32Command ((LPSRB)&s);

  1319. 

  1320.     if (status == SS_PENDING)

  1321.         WaitForSingleObject (event, 4000);

  1322. 

  1323.     CloseHandle (event);

  1324. }

  1325. 

  1326. bool CDDeviceHandle::testController (const int type,

  1327.                                      CDController* const newController,

  1328.                                      CDReadBuffer* const rb)

  1329. {

  1330.     controller = newController;

  1331.     readType = (BYTE)type;

  1332. 

  1333.     controller->deviceInfo = this;

  1334.     controller->framesToCheck = 1;

  1335.     controller->framesOverlap = 3;

  1336. 

  1337.     bool passed = false;

  1338. 

  1339.     memset (rb->buffer, 0xcd, rb->bufferSize);

  1340. 

  1341.     if (controller->read (rb))

  1342.     {

  1343.         passed = true;

  1344.         int* p = (int*) (rb->buffer + rb->dataStartOffset);

  1345.         int wrong = 0;

  1346. 

  1347.         for (int i = rb->dataLength / 4; --i >= 0;)

  1348.         {

  1349.             if (*p++ == (int) 0xcdcdcdcd)

  1350.             {

  1351.                 if (++wrong == 4)

  1352.                 {

  1353.                     passed = false;

  1354.                     break;

  1355.                 }

  1356.             }

  1357.             else

  1358.             {

  1359.                 wrong = 0;

  1360.             }

  1361.         }

  1362.     }

  1363. 

  1364.     if (! passed)

  1365.     {

  1366.         controller->shutDown();

  1367.         delete controller;

  1368.         controller = 0;

  1369.     }

  1370. 

  1371.     return passed;

  1372. }

  1373. 

  1374. 

  1375. //==============================================================================

  1376. static void GetAspiDeviceInfo (CDDeviceInfo* dev, BYTE ha, BYTE tgt, BYTE lun)

  1377. {

  1378.     HANDLE event = CreateEvent (0, TRUE, FALSE, 0);

  1379. 

  1380.     const int bufSize = 128;

  1381.     BYTE buffer[bufSize];

  1382.     zeromem (buffer, bufSize);

  1383. 

  1384.     SRB_ExecSCSICmd s;

  1385.     zerostruct (s);

  1386. 

  1387.     s.SRB_Cmd        = SC_EXEC_SCSI_CMD;

  1388.     s.SRB_HaID       = ha;

  1389.     s.SRB_Target     = tgt;

  1390.     s.SRB_Lun        = lun;

  1391.     s.SRB_Flags      = SRB_DIR_IN | SRB_EVENT_NOTIFY;

  1392.     s.SRB_BufLen     = bufSize;

  1393.     s.SRB_BufPointer = buffer;

  1394.     s.SRB_SenseLen   = SENSE_LEN;

  1395.     s.SRB_CDBLen     = 6;

  1396.     s.SRB_PostProc   = (void*)event;

  1397.     s.CDBByte[0]     = SCSI_INQUIRY;

  1398.     s.CDBByte[4]     = 100;

  1399. 

  1400.     ResetEvent (event);

  1401. 

  1402.     if (fSendASPI32Command ((LPSRB)&s) == SS_PENDING)

  1403.         WaitForSingleObject (event, 4000);

  1404. 

  1405.     CloseHandle (event);

  1406. 

  1407.     if (s.SRB_Status == SS_COMP)

  1408.     {

  1409.         memcpy (dev->vendor,     &buffer[8], 8);

  1410.         memcpy (dev->productId,  &buffer[16], 16);

  1411.         memcpy (dev->rev,        &buffer[32], 4);

  1412.         memcpy (dev->vendorSpec, &buffer[36], 20);

  1413.     }

  1414. }

  1415. 

  1416. static int FindCDDevices (CDDeviceInfo* const list,

  1417.                           int maxItems)

  1418. {

  1419.     int count = 0;

  1420. 

  1421.     if (usingScsi)

  1422.     {

  1423.         for (char driveLetter = 'b'; driveLetter <= 'z'; ++driveLetter)

  1424.         {

  1425.             TCHAR drivePath[8];

  1426.             drivePath[0] = driveLetter;

  1427.             drivePath[1] = ':';

  1428.             drivePath[2] = '\\';

  1429.             drivePath[3] = 0;

  1430. 

  1431.             if (GetDriveType (drivePath) == DRIVE_CDROM)

  1432.             {

  1433.                 HANDLE h = CreateSCSIDeviceHandle (driveLetter);

  1434. 

  1435.                 if (h != INVALID_HANDLE_VALUE)

  1436.                 {

  1437.                     BYTE buffer[100], passThroughStruct[1024];

  1438.                     zeromem (buffer, sizeof (buffer));

  1439.                     zeromem (passThroughStruct, sizeof (passThroughStruct));

  1440. 

  1441.                     PSCSI_PASS_THROUGH_DIRECT_WITH_BUFFER p = (PSCSI_PASS_THROUGH_DIRECT_WITH_BUFFER)passThroughStruct;

  1442. 

  1443.                     p->spt.Length             = sizeof (SCSI_PASS_THROUGH);

  1444.                     p->spt.CdbLength          = 6;

  1445.                     p->spt.SenseInfoLength    = 24;

  1446.                     p->spt.DataIn             = SCSI_IOCTL_DATA_IN;

  1447.                     p->spt.DataTransferLength = 100;

  1448.                     p->spt.TimeOutValue       = 2;

  1449.                     p->spt.DataBuffer         = buffer;

  1450.                     p->spt.SenseInfoOffset    = offsetof (SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER, ucSenseBuf);

  1451.                     p->spt.Cdb[0]             = 0x12;

  1452.                     p->spt.Cdb[4]             = 100;

  1453. 

  1454.                     DWORD bytesReturned = 0;

  1455. 

  1456.                     if (DeviceIoControl (h, IOCTL_SCSI_PASS_THROUGH_DIRECT,

  1457.                                          p, sizeof (SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER),

  1458.                                          p, sizeof (SCSI_PASS_THROUGH_DIRECT_WITH_BUFFER),

  1459.                                          &bytesReturned, 0) != 0)

  1460.                     {

  1461.                         zeromem (&list[count], sizeof (CDDeviceInfo));

  1462. 

  1463.                         list[count].scsiDriveLetter = driveLetter;

  1464. 

  1465.                         memcpy (list[count].vendor,     &buffer[8], 8);

  1466.                         memcpy (list[count].productId,  &buffer[16], 16);

  1467.                         memcpy (list[count].rev,        &buffer[32], 4);

  1468.                         memcpy (list[count].vendorSpec, &buffer[36], 20);

  1469. 

  1470.                         zeromem (passThroughStruct, sizeof (passThroughStruct));

  1471.                         PSCSI_ADDRESS scsiAddr = (PSCSI_ADDRESS)passThroughStruct;

  1472. 

  1473.                         scsiAddr->Length = sizeof (SCSI_ADDRESS);

  1474. 

  1475.                         if (DeviceIoControl (h, IOCTL_SCSI_GET_ADDRESS,

  1476.                                              0, 0, scsiAddr, sizeof (SCSI_ADDRESS),

  1477.                                              &bytesReturned, 0) != 0)

  1478.                         {

  1479.                             list[count].ha = scsiAddr->PortNumber;

  1480.                             list[count].tgt = scsiAddr->TargetId;

  1481.                             list[count].lun = scsiAddr->Lun;

  1482.                             ++count;

  1483.                         }

  1484.                     }

  1485. 

  1486.                     CloseHandle (h);

  1487.                 }

  1488.             }

  1489.         }

  1490.     }

  1491.     else

  1492.     {

  1493.         const DWORD d = fGetASPI32SupportInfo();

  1494.         BYTE status = HIBYTE (LOWORD (d));

  1495. 

  1496.         if (status != SS_COMP || status == SS_NO_ADAPTERS)

  1497.             return 0;

  1498. 

  1499.         const int numAdapters = LOBYTE (LOWORD (d));

  1500. 

  1501.         for (BYTE ha = 0; ha < numAdapters; ++ha)

  1502.         {

  1503.             SRB_HAInquiry s;

  1504.             zerostruct (s);

  1505. 

  1506.             s.SRB_Cmd = SC_HA_INQUIRY;

  1507.             s.SRB_HaID = ha;

  1508.             fSendASPI32Command ((LPSRB)&s);

  1509. 

  1510.             if (s.SRB_Status == SS_COMP)

  1511.             {

  1512.                 maxItems = (int)s.HA_Unique[3];

  1513. 

  1514.                 if (maxItems == 0)

  1515.                     maxItems = 8;

  1516. 

  1517.                 for (BYTE tgt = 0; tgt < maxItems; ++tgt)

  1518.                 {

  1519.                     for (BYTE lun = 0; lun < 8; ++lun)

  1520.                     {

  1521.                         SRB_GDEVBlock sb;

  1522.                         zerostruct (sb);

  1523. 

  1524.                         sb.SRB_Cmd = SC_GET_DEV_TYPE;

  1525.                         sb.SRB_HaID = ha;

  1526.                         sb.SRB_Target = tgt;

  1527.                         sb.SRB_Lun = lun;

  1528.                         fSendASPI32Command ((LPSRB) &sb);

  1529. 

  1530.                         if (sb.SRB_Status == SS_COMP

  1531.                              && sb.SRB_DeviceType == DTYPE_CROM)

  1532.                         {

  1533.                             zeromem (&list[count], sizeof (CDDeviceInfo));

  1534. 

  1535.                             list[count].ha = ha;

  1536.                             list[count].tgt = tgt;

  1537.                             list[count].lun = lun;

  1538. 

  1539.                             GetAspiDeviceInfo (&(list[count]), ha, tgt, lun);

  1540. 

  1541.                             ++count;

  1542.                         }

  1543.                     }

  1544.                 }

  1545.             }

  1546.         }

  1547.     }

  1548. 

  1549.     return count;

  1550. }

  1551. 

  1552. 

  1553. //==============================================================================

  1554. static int ripperUsers = 0;

  1555. static bool initialisedOk = false;

  1556. 

  1557. class DeinitialiseTimer  : private Timer,

  1558.                            private DeletedAtShutdown

  1559. {

  1560.     DeinitialiseTimer (const DeinitialiseTimer&);

  1561.     const DeinitialiseTimer& operator= (const DeinitialiseTimer&);

  1562. 

  1563. public:

  1564.     DeinitialiseTimer()

  1565.     {

  1566.         startTimer (4000);

  1567.     }

  1568. 

  1569.     ~DeinitialiseTimer()

  1570.     {

  1571.         if (--ripperUsers == 0)

  1572.             DeinitialiseCDRipper();

  1573.     }

  1574. 

  1575.     void timerCallback()

  1576.     {

  1577.         delete this;

  1578.     }

  1579. 

  1580.     juce_UseDebuggingNewOperator

  1581. };

  1582. 

  1583. static void incUserCount()

  1584. {

  1585.     if (ripperUsers++ == 0)

  1586.         initialisedOk = InitialiseCDRipper();

  1587. }

  1588. 

  1589. static void decUserCount()

  1590. {

  1591.     new DeinitialiseTimer();

  1592. }

  1593. 

  1594. //==============================================================================

  1595. struct CDDeviceWrapper

  1596. {

  1597.     CDDeviceHandle* cdH;

  1598.     CDReadBuffer* overlapBuffer;

  1599.     bool jitter;

  1600. };

  1601. 

  1602. //==============================================================================

  1603. static int getAddressOf (const TOCTRACK* const t)

  1604. {

  1605.     return (((DWORD)t->addr[0]) << 24) + (((DWORD)t->addr[1]) << 16) +

  1606.            (((DWORD)t->addr[2]) << 8) + ((DWORD)t->addr[3]);

  1607. }

  1608. 

  1609. static int getMSFAddressOf (const TOCTRACK* const t)

  1610. {

  1611.     return 60 * t->addr[1] + t->addr[2];

  1612. }

  1613. 

  1614. static const int samplesPerFrame = 44100 / 75;

  1615. static const int bytesPerFrame = samplesPerFrame * 4;

  1616. 

  1617. 

  1618. //==============================================================================

  1619. const StringArray AudioCDReader::getAvailableCDNames()

  1620. {

  1621.     StringArray results;

  1622.     incUserCount();

  1623. 

  1624.     if (initialisedOk)

  1625.     {

  1626.         CDDeviceInfo list[8];

  1627.         const int num = FindCDDevices (list, 8);

  1628. 

  1629.         decUserCount();

  1630. 

  1631.         for (int i = 0; i < num; ++i)

  1632.         {

  1633.             String s;

  1634. 

  1635.             if (list[i].scsiDriveLetter > 0)

  1636.                 s << String::charToString (list[i].scsiDriveLetter).toUpperCase() << T(": ");

  1637. 

  1638.             s << String (list[i].vendor).trim()

  1639.               << T(" ") << String (list[i].productId).trim()

  1640.               << T(" ") << String (list[i].rev).trim();

  1641. 

  1642.             results.add (s);

  1643.         }

  1644.     }

  1645. 

  1646.     return results;

  1647. }

  1648. 

  1649. static CDDeviceHandle* openHandle (const CDDeviceInfo* const device)

  1650. {

  1651.     SRB_GDEVBlock s;

  1652.     zerostruct (s);

  1653. 

  1654.     s.SRB_Cmd = SC_GET_DEV_TYPE;

  1655.     s.SRB_HaID = device->ha;

  1656.     s.SRB_Target = device->tgt;

  1657.     s.SRB_Lun = device->lun;

  1658. 

  1659.     if (usingScsi)

  1660.     {

  1661.         HANDLE h = CreateSCSIDeviceHandle (device->scsiDriveLetter);

  1662. 

  1663.         if (h != INVALID_HANDLE_VALUE)

  1664.         {

  1665.             CDDeviceHandle* cdh = new CDDeviceHandle (device);

  1666.             cdh->scsiHandle = h;

  1667.             return cdh;

  1668.         }

  1669.     }

  1670.     else

  1671.     {

  1672.         if (fSendASPI32Command ((LPSRB)&s) == SS_COMP

  1673.              && s.SRB_DeviceType == DTYPE_CROM)

  1674.         {

  1675.             return new CDDeviceHandle (device);

  1676.         }

  1677.     }

  1678. 

  1679.     return 0;

  1680. }

  1681. 

  1682. AudioCDReader* AudioCDReader::createReaderForCD (const int deviceIndex)

  1683. {

  1684.     incUserCount();

  1685. 

  1686.     if (initialisedOk)

  1687.     {

  1688.         CDDeviceInfo list[8];

  1689.         const int num = FindCDDevices (list, 8);

  1690. 

  1691.         if (((unsigned int) deviceIndex) < (unsigned int) num)

  1692.         {

  1693.             CDDeviceHandle* const handle = openHandle (&(list[deviceIndex]));

  1694. 

  1695.             if (handle != 0)

  1696.             {

  1697.                 CDDeviceWrapper* const d = new CDDeviceWrapper();

  1698.                 d->cdH = handle;

  1699.                 d->overlapBuffer = new CDReadBuffer(3);

  1700. 

  1701.                 return new AudioCDReader (d);

  1702.             }

  1703.         }

  1704.     }

  1705. 

  1706.     decUserCount();

  1707.     return 0;

  1708. }

  1709. 

  1710. AudioCDReader::AudioCDReader (void* handle_)

  1711.     : AudioFormatReader (0, T("CD Audio")),

  1712.       handle (handle_),

  1713.       indexingEnabled (false),

  1714.       lastIndex (0),

  1715.       firstFrameInBuffer (0),

  1716.       samplesInBuffer (0)

  1717. {

  1718.     jassert (handle_ != 0);

  1719. 

  1720.     refreshTrackLengths();

  1721. 

  1722.     sampleRate = 44100.0;

  1723.     bitsPerSample = 16;

  1724.     lengthInSamples = getPositionOfTrackStart (numTracks);

  1725.     numChannels = 2;

  1726.     usesFloatingPointData = false;

  1727. 

  1728.     buffer.setSize (4 * bytesPerFrame, true);

  1729. }

  1730. 

  1731. AudioCDReader::~AudioCDReader()

  1732. {

  1733.     CDDeviceWrapper* const device = (CDDeviceWrapper*)handle;

  1734. 

  1735.     delete device->cdH;

  1736.     delete device->overlapBuffer;

  1737.     delete device;

  1738. 

  1739.     decUserCount();

  1740. }

  1741. 

  1742. bool AudioCDReader::readSamples (int** destSamples, int numDestChannels, int startOffsetInDestBuffer,

  1743.                                  int64 startSampleInFile, int numSamples)

  1744. {

  1745.     CDDeviceWrapper* const device = (CDDeviceWrapper*) handle;

  1746. 

  1747.     bool ok = true;

  1748. 

  1749.     while (numSamples > 0)

  1750.     {

  1751.         const int bufferStartSample = firstFrameInBuffer * samplesPerFrame;

  1752.         const int bufferEndSample = bufferStartSample + samplesInBuffer;

  1753. 

  1754.         if (startSampleInFile >= bufferStartSample

  1755.              && startSampleInFile < bufferEndSample)

  1756.         {

  1757.             const int toDo = (int) jmin ((int64) numSamples, bufferEndSample - startSampleInFile);

  1758. 

  1759.             int* const l = destSamples[0] + startOffsetInDestBuffer;

  1760.             int* const r = numDestChannels > 1 ? (destSamples[1] + startOffsetInDestBuffer) : 0;

  1761.             const short* src = (const short*) buffer.getData();

  1762.             src += 2 * (startSampleInFile - bufferStartSample);

  1763. 

  1764.             for (int i = 0; i < toDo; ++i)

  1765.             {

  1766.                 l[i] = src [i << 1] << 16;

  1767. 

  1768.                 if (r != 0)

  1769.                     r[i] = src [(i << 1) + 1] << 16;

  1770.             }

  1771. 

  1772.             startOffsetInDestBuffer += toDo;

  1773.             startSampleInFile += toDo;

  1774.             numSamples -= toDo;

  1775.         }

  1776.         else

  1777.         {

  1778.             const int framesInBuffer = buffer.getSize() / bytesPerFrame;

  1779.             const int frameNeeded = (int) (startSampleInFile / samplesPerFrame);

  1780. 

  1781.             if (firstFrameInBuffer + framesInBuffer != frameNeeded)

  1782.             {

  1783.                 device->overlapBuffer->dataLength = 0;

  1784.                 device->overlapBuffer->startFrame = 0;

  1785.                 device->overlapBuffer->numFrames = 0;

  1786.                 device->jitter = false;

  1787.             }

  1788. 

  1789.             firstFrameInBuffer = frameNeeded;

  1790.             lastIndex = 0;

  1791. 

  1792.             CDReadBuffer readBuffer (framesInBuffer + 4);

  1793.             readBuffer.wantsIndex = indexingEnabled;

  1794. 

  1795.             int i;

  1796.             for (i = 5; --i >= 0;)

  1797.             {

  1798.                 readBuffer.startFrame = frameNeeded;

  1799.                 readBuffer.numFrames = framesInBuffer;

  1800. 

  1801.                 if (device->cdH->readAudio (&readBuffer, (device->jitter) ? device->overlapBuffer : 0))

  1802.                     break;

  1803.                 else

  1804.                     device->overlapBuffer->dataLength = 0;

  1805.             }

  1806. 

  1807.             if (i >= 0)

  1808.             {

  1809.                 memcpy ((char*) buffer.getData(),

  1810.                         readBuffer.buffer + readBuffer.dataStartOffset,

  1811.                         readBuffer.dataLength);

  1812. 

  1813.                 samplesInBuffer = readBuffer.dataLength >> 2;

  1814.                 lastIndex = readBuffer.index;

  1815.             }

  1816.             else

  1817.             {

  1818.                 int* l = destSamples[0] + startOffsetInDestBuffer;

  1819.                 int* r = numDestChannels > 1 ? (destSamples[1] + startOffsetInDestBuffer) : 0;

  1820. 

  1821.                 while (--numSamples >= 0)

  1822.                 {

  1823.                     *l++ = 0;

  1824. 

  1825.                     if (r != 0)

  1826.                         *r++ = 0;

  1827.                 }

  1828. 

  1829.                 // sometimes the read fails for just the very last couple of blocks, so

  1830.                 // we'll ignore and errors in the last half-second of the disk..

  1831.                 ok = startSampleInFile > (trackStarts [numTracks] - 20000);

  1832.                 break;

  1833.             }

  1834.         }

  1835.     }

  1836. 

  1837.     return ok;

  1838. }

  1839. 

  1840. bool AudioCDReader::isCDStillPresent() const

  1841. {

  1842.     TOC toc;

  1843.     zerostruct (toc);

  1844. 

  1845.     return ((CDDeviceWrapper*)handle)->cdH->readTOC (&toc, false);

  1846. }

  1847. 

  1848. int AudioCDReader::getNumTracks() const

  1849. {

  1850.     return numTracks;

  1851. }

  1852. 

  1853. int AudioCDReader::getPositionOfTrackStart (int trackNum) const

  1854. {

  1855.     return (trackNum >= 0 && trackNum <= numTracks) ? trackStarts [trackNum] * samplesPerFrame

  1856.                                                     : 0;

  1857. }

  1858. 

  1859. void AudioCDReader::refreshTrackLengths()

  1860. {

  1861.     zeromem (trackStarts, sizeof (trackStarts));

  1862.     zeromem (audioTracks, sizeof (audioTracks));

  1863. 

  1864.     TOC toc;

  1865.     zerostruct (toc);

  1866. 

  1867.     if (((CDDeviceWrapper*)handle)->cdH->readTOC (&toc, false))

  1868.     {

  1869.         numTracks = 1 + toc.lastTrack - toc.firstTrack;

  1870. 

  1871.         for (int i = 0; i <= numTracks; ++i)

  1872.         {

  1873.             trackStarts[i] = getAddressOf (&toc.tracks[i]);

  1874.             audioTracks[i] = ((toc.tracks[i].ADR & 4) == 0);

  1875.         }

  1876.     }

  1877.     else

  1878.     {

  1879.         numTracks = 0;

  1880.     }

  1881. }

  1882. 

  1883. bool AudioCDReader::isTrackAudio (int trackNum) const

  1884. {

  1885.     return (trackNum >= 0 && trackNum <= numTracks) ? audioTracks [trackNum]

  1886.                                                     : false;

  1887. }

  1888. 

  1889. void AudioCDReader::enableIndexScanning (bool b)

  1890. {

  1891.     indexingEnabled = b;

  1892. }

  1893. 

  1894. int AudioCDReader::getLastIndex() const

  1895. {

  1896.     return lastIndex;

  1897. }

  1898. 

  1899. const int framesPerIndexRead = 4;

  1900. 

  1901. int AudioCDReader::getIndexAt (int samplePos)

  1902. {

  1903.     CDDeviceWrapper* const device = (CDDeviceWrapper*) handle;

  1904. 

  1905.     const int frameNeeded = samplePos / samplesPerFrame;

  1906. 

  1907.     device->overlapBuffer->dataLength = 0;

  1908.     device->overlapBuffer->startFrame = 0;

  1909.     device->overlapBuffer->numFrames = 0;

  1910.     device->jitter = false;

  1911. 

  1912.     firstFrameInBuffer = 0;

  1913.     lastIndex = 0;

  1914. 

  1915.     CDReadBuffer readBuffer (4 + framesPerIndexRead);

  1916.     readBuffer.wantsIndex = true;

  1917. 

  1918.     int i;

  1919.     for (i = 5; --i >= 0;)

  1920.     {

  1921.         readBuffer.startFrame = frameNeeded;

  1922.         readBuffer.numFrames = framesPerIndexRead;

  1923. 

  1924.         if (device->cdH->readAudio (&readBuffer, (false) ? device->overlapBuffer : 0))

  1925.             break;

  1926.     }

  1927. 

  1928.     if (i >= 0)

  1929.         return readBuffer.index;

  1930. 

  1931.     return -1;

  1932. }

  1933. 

  1934. const Array <int> AudioCDReader::findIndexesInTrack (const int trackNumber)

  1935. {

  1936.     Array <int> indexes;

  1937. 

  1938.     const int trackStart = getPositionOfTrackStart (trackNumber);

  1939.     const int trackEnd = getPositionOfTrackStart (trackNumber + 1);

  1940. 

  1941.     bool needToScan = true;

  1942. 

  1943.     if (trackEnd - trackStart > 20 * 44100)

  1944.     {

  1945.         // check the end of the track for indexes before scanning the whole thing

  1946.         needToScan = false;

  1947.         int pos = jmax (trackStart, trackEnd - 44100 * 5);

  1948.         bool seenAnIndex = false;

  1949. 

  1950.         while (pos <= trackEnd - samplesPerFrame)

  1951.         {

  1952.             const int index = getIndexAt (pos);

  1953. 

  1954.             if (index == 0)

  1955.             {

  1956.                 // lead-out, so skip back a bit if we've not found any indexes yet..

  1957.                 if (seenAnIndex)

  1958.                     break;

  1959. 

  1960.                 pos -= 44100 * 5;

  1961. 

  1962.                 if (pos < trackStart)

  1963.                     break;

  1964.             }

  1965.             else

  1966.             {

  1967.                 if (index > 0)

  1968.                     seenAnIndex = true;

  1969. 

  1970.                 if (index > 1)

  1971.                 {

  1972.                     needToScan = true;

  1973.                     break;

  1974.                 }

  1975. 

  1976.                 pos += samplesPerFrame * framesPerIndexRead;

  1977.             }

  1978.         }

  1979.     }

  1980. 

  1981.     if (needToScan)

  1982.     {

  1983.         CDDeviceWrapper* const device = (CDDeviceWrapper*) handle;

  1984. 

  1985.         int pos = trackStart;

  1986.         int last = -1;

  1987. 

  1988.         while (pos < trackEnd - samplesPerFrame * 10)

  1989.         {

  1990.             const int frameNeeded = pos / samplesPerFrame;

  1991. 

  1992.             device->overlapBuffer->dataLength = 0;

  1993.             device->overlapBuffer->startFrame = 0;

  1994.             device->overlapBuffer->numFrames = 0;

  1995.             device->jitter = false;

  1996. 

  1997.             firstFrameInBuffer = 0;

  1998. 

  1999.             CDReadBuffer readBuffer (4);

  2000.             readBuffer.wantsIndex = true;

  2001. 

  2002.             int i;

  2003.             for (i = 5; --i >= 0;)

  2004.             {

  2005.                 readBuffer.startFrame = frameNeeded;

  2006.                 readBuffer.numFrames = framesPerIndexRead;

  2007. 

  2008.                 if (device->cdH->readAudio (&readBuffer, (false) ? device->overlapBuffer : 0))

  2009.                     break;

  2010.             }

  2011. 

  2012.             if (i < 0)

  2013.                 break;

  2014. 

  2015.             if (readBuffer.index > last && readBuffer.index > 1)

  2016.             {

  2017.                 last = readBuffer.index;

  2018.                 indexes.add (pos);

  2019.             }

  2020. 

  2021.             pos += samplesPerFrame * framesPerIndexRead;

  2022.         }

  2023. 

  2024.         indexes.removeValue (trackStart);

  2025.     }

  2026. 

  2027.     return indexes;

  2028. }

  2029. 

  2030. int AudioCDReader::getCDDBId()

  2031. {

  2032.     refreshTrackLengths();

  2033. 

  2034.     if (numTracks > 0)

  2035.     {

  2036.         TOC toc;

  2037.         zerostruct (toc);

  2038. 

  2039.         if (((CDDeviceWrapper*) handle)->cdH->readTOC (&toc, true))

  2040.         {

  2041.             int n = 0;

  2042. 

  2043.             for (int i = numTracks; --i >= 0;)

  2044.             {

  2045.                 int j = getMSFAddressOf (&toc.tracks[i]);

  2046. 

  2047.                 while (j > 0)

  2048.                 {

  2049.                     n += (j % 10);

  2050.                     j /= 10;

  2051.                 }

  2052.             }

  2053. 

  2054.             if (n != 0)

  2055.             {

  2056.                 const int t = getMSFAddressOf (&toc.tracks[numTracks])

  2057.                                 - getMSFAddressOf (&toc.tracks[0]);

  2058. 

  2059.                 return ((n % 0xff) << 24) | (t << 8) | numTracks;

  2060.             }

  2061.         }

  2062.     }

  2063. 

  2064.     return 0;

  2065. }

  2066. 

  2067. void AudioCDReader::ejectDisk()

  2068. {

  2069.     ((CDDeviceWrapper*) handle)->cdH->openDrawer (true);

  2070. }

  2071. 

  2072. 

  2073. //==============================================================================

  2074. static IDiscRecorder* enumCDBurners (StringArray* list, int indexToOpen, IDiscMaster** master)

  2075. {

  2076.     CoInitialize (0);

  2077. 

  2078.     IDiscMaster* dm;

  2079.     IDiscRecorder* result = 0;

  2080. 

  2081.     if (SUCCEEDED (CoCreateInstance (CLSID_MSDiscMasterObj, 0,

  2082.                                      CLSCTX_INPROC_SERVER | CLSCTX_LOCAL_SERVER,

  2083.                                      IID_IDiscMaster,

  2084.                                      (void**) &dm)))

  2085.     {

  2086.         if (SUCCEEDED (dm->Open()))

  2087.         {

  2088.             IEnumDiscRecorders* drEnum = 0;

  2089. 

  2090.             if (SUCCEEDED (dm->EnumDiscRecorders (&drEnum)))

  2091.             {

  2092.                 IDiscRecorder* dr = 0;

  2093.                 DWORD dummy;

  2094.                 int index = 0;

  2095. 

  2096.                 while (drEnum->Next (1, &dr, &dummy) == S_OK)

  2097.                 {

  2098.                     if (indexToOpen == index)

  2099.                     {

  2100.                         result = dr;

  2101.                         break;

  2102.                     }

  2103.                     else if (list != 0)

  2104.                     {

  2105.                         BSTR path;

  2106. 

  2107.                         if (SUCCEEDED (dr->GetPath (&path)))

  2108.                             list->add ((const WCHAR*) path);

  2109.                     }

  2110. 

  2111.                     ++index;

  2112.                     dr->Release();

  2113.                 }

  2114. 

  2115.                 drEnum->Release();

  2116.             }

  2117. 

  2118.             /*if (redbookFormat != 0)

  2119.             {

  2120.                 IEnumDiscMasterFormats* mfEnum;

  2121. 

  2122.                 if (SUCCEEDED (dm->EnumDiscMasterFormats (&mfEnum)))

  2123.                 {

  2124.                     IID formatIID;

  2125.                     DWORD dummy;

  2126. 

  2127.                     while (mfEnum->Next (1, &formatIID, &dummy) == S_OK)

  2128.                     {

  2129.                     }

  2130. 

  2131.                     mfEnum->Release();

  2132.                 }

  2133. 

  2134.                 redbookFormat

  2135.             }*/

  2136. 

  2137.             if (master == 0)

  2138.                 dm->Close();

  2139.         }

  2140. 

  2141.         if (master != 0)

  2142.             *master = dm;

  2143.         else

  2144.             dm->Release();

  2145.     }

  2146. 

  2147.     return result;

  2148. }

  2149. 

  2150. const StringArray AudioCDBurner::findAvailableDevices()

  2151. {

  2152.     StringArray devs;

  2153.     enumCDBurners (&devs, -1, 0);

  2154.     return devs;

  2155. }

  2156. 

  2157. AudioCDBurner* AudioCDBurner::openDevice (const int deviceIndex)

  2158. {

  2159.     AudioCDBurner* b = new AudioCDBurner (deviceIndex);

  2160. 

  2161.     if (b->internal == 0)

  2162.         deleteAndZero (b);

  2163. 

  2164.     return b;

  2165. }

  2166. 

  2167. class CDBurnerInfo  : public IDiscMasterProgressEvents

  2168. {

  2169. public:

  2170.     CDBurnerInfo()

  2171.         : refCount (1),

  2172.           progress (0),

  2173.           shouldCancel (false),

  2174.           listener (0)

  2175.     {

  2176.     }

  2177. 

  2178.     ~CDBurnerInfo()

  2179.     {

  2180.     }

  2181. 

  2182.     HRESULT __stdcall QueryInterface (REFIID id, void __RPC_FAR* __RPC_FAR* result)

  2183.     {

  2184.         if (result == 0)

  2185.             return E_POINTER;

  2186. 

  2187.         if (id == IID_IUnknown || id == IID_IDiscMasterProgressEvents)

  2188.         {

  2189.             AddRef();

  2190.             *result = this;

  2191.             return S_OK;

  2192.         }

  2193. 

  2194.         *result = 0;

  2195.         return E_NOINTERFACE;

  2196.     }

  2197. 

  2198.     ULONG __stdcall AddRef()    { return ++refCount; }

  2199.     ULONG __stdcall Release()   { jassert (refCount > 0); const int r = --refCount; if (r == 0) delete this; return r; }

  2200. 

  2201.     HRESULT __stdcall QueryCancel (boolean* pbCancel)

  2202.     {

  2203.         if (listener != 0 && ! shouldCancel)

  2204.             shouldCancel = listener->audioCDBurnProgress (progress);

  2205. 

  2206.         *pbCancel = shouldCancel;

  2207. 

  2208.         return S_OK;

  2209.     }

  2210. 

  2211.     HRESULT __stdcall NotifyBlockProgress (long nCompleted, long nTotal)

  2212.     {

  2213.         progress = nCompleted / (float) nTotal;

  2214.         shouldCancel = listener != 0 && listener->audioCDBurnProgress (progress);

  2215. 

  2216.         return E_NOTIMPL;

  2217.     }

  2218. 

  2219.     HRESULT __stdcall NotifyPnPActivity (void)                              { return E_NOTIMPL; }

  2220.     HRESULT __stdcall NotifyAddProgress (long /*nCompletedSteps*/, long /*nTotalSteps*/)    { return E_NOTIMPL; }

  2221.     HRESULT __stdcall NotifyTrackProgress (long /*nCurrentTrack*/, long /*nTotalTracks*/)   { return E_NOTIMPL; }

  2222.     HRESULT __stdcall NotifyPreparingBurn (long /*nEstimatedSeconds*/)      { return E_NOTIMPL; }

  2223.     HRESULT __stdcall NotifyClosingDisc (long /*nEstimatedSeconds*/)        { return E_NOTIMPL; }

  2224.     HRESULT __stdcall NotifyBurnComplete (HRESULT /*status*/)               { return E_NOTIMPL; }

  2225.     HRESULT __stdcall NotifyEraseComplete (HRESULT /*status*/)              { return E_NOTIMPL; }

  2226. 

  2227.     IDiscMaster* discMaster;

  2228.     IDiscRecorder* discRecorder;

  2229.     IRedbookDiscMaster* redbook;

  2230.     AudioCDBurner::BurnProgressListener* listener;

  2231.     float progress;

  2232.     bool shouldCancel;

  2233. 

  2234. private:

  2235.     int refCount;

  2236. };

  2237. 

  2238. AudioCDBurner::AudioCDBurner (const int deviceIndex)

  2239.     : internal (0)

  2240. {

  2241.     IDiscMaster* discMaster;

  2242.     IDiscRecorder* dr = enumCDBurners (0, deviceIndex, &discMaster);

  2243. 

  2244.     if (dr != 0)

  2245.     {

  2246.         IRedbookDiscMaster* redbook;

  2247.         HRESULT hr = discMaster->SetActiveDiscMasterFormat (IID_IRedbookDiscMaster, (void**) &redbook);

  2248. 

  2249.         hr = discMaster->SetActiveDiscRecorder (dr);

  2250. 

  2251.         CDBurnerInfo* const info = new CDBurnerInfo();

  2252.         internal = info;

  2253. 

  2254.         info->discMaster = discMaster;

  2255.         info->discRecorder = dr;

  2256.         info->redbook = redbook;

  2257.     }

  2258. }

  2259. 

  2260. AudioCDBurner::~AudioCDBurner()

  2261. {

  2262.     CDBurnerInfo* const info = (CDBurnerInfo*) internal;

  2263. 

  2264.     if (info != 0)

  2265.     {

  2266.         info->discRecorder->Close();

  2267.         info->redbook->Release();

  2268.         info->discRecorder->Release();

  2269.         info->discMaster->Release();

  2270. 

  2271.         info->Release();

  2272.     }

  2273. }

  2274. 

  2275. bool AudioCDBurner::isDiskPresent() const

  2276. {

  2277.     CDBurnerInfo* const info = (CDBurnerInfo*) internal;

  2278. 

  2279.     HRESULT hr = info->discRecorder->OpenExclusive();

  2280. 

  2281.     long type, flags;

  2282.     hr = info->discRecorder->QueryMediaType (&type, &flags);

  2283. 

  2284.     info->discRecorder->Close();

  2285.     return hr == S_OK && type != 0 && (flags & MEDIA_WRITABLE) != 0;

  2286. }

  2287. 

  2288. int AudioCDBurner::getNumAvailableAudioBlocks() const

  2289. {

  2290.     CDBurnerInfo* const info = (CDBurnerInfo*) internal;

  2291.     long blocksFree = 0;

  2292.     info->redbook->GetAvailableAudioTrackBlocks (&blocksFree);

  2293.     return blocksFree;

  2294. }

  2295. 

  2296. const String AudioCDBurner::burn (AudioCDBurner::BurnProgressListener* listener,

  2297.                                   const bool ejectDiscAfterwards,

  2298.                                   const bool performFakeBurnForTesting)

  2299. {

  2300.     CDBurnerInfo* const info = (CDBurnerInfo*) internal;

  2301. 

  2302.     info->listener = listener;

  2303.     info->progress = 0;

  2304.     info->shouldCancel = false;

  2305. 

  2306.     UINT_PTR cookie;

  2307.     HRESULT hr = info->discMaster->ProgressAdvise (info, &cookie);

  2308. 

  2309.     hr = info->discMaster->RecordDisc (performFakeBurnForTesting,

  2310.                                        ejectDiscAfterwards);

  2311. 

  2312.     String error;

  2313.     if (hr != S_OK)

  2314.     {

  2315.         const char* e = "Couldn't open or write to the CD device";

  2316. 

  2317.         if (hr == IMAPI_E_USERABORT)

  2318.             e = "User cancelled the write operation";

  2319.         else if (hr == IMAPI_E_MEDIUM_NOTPRESENT || hr == IMAPI_E_TRACKOPEN)

  2320.             e = "No Disk present";

  2321. 

  2322.         error = e;

  2323.     }

  2324. 

  2325.     info->discMaster->ProgressUnadvise (cookie);

  2326.     info->listener = 0;

  2327. 

  2328.     return error;

  2329. }

  2330. 

  2331. bool AudioCDBurner::addAudioTrack (AudioSource* source, int numSamples)

  2332. {

  2333.     if (source == 0)

  2334.         return false;

  2335. 

  2336.     CDBurnerInfo* const info = (CDBurnerInfo*) internal;

  2337. 

  2338.     long bytesPerBlock;

  2339.     HRESULT hr = info->redbook->GetAudioBlockSize (&bytesPerBlock);

  2340. 

  2341.     const int samplesPerBlock = bytesPerBlock / 4;

  2342.     bool ok = true;

  2343. 

  2344.     hr = info->redbook->CreateAudioTrack ((long) numSamples / (bytesPerBlock * 4));

  2345. 

  2346.     byte* const buffer = (byte*) juce_malloc (bytesPerBlock);

  2347. 

  2348.     AudioSampleBuffer sourceBuffer (2, samplesPerBlock);

  2349.     int samplesDone = 0;

  2350. 

  2351.     source->prepareToPlay (samplesPerBlock, 44100.0);

  2352. 

  2353.     while (ok)

  2354.     {

  2355.         {

  2356.             AudioSourceChannelInfo info;

  2357.             info.buffer = &sourceBuffer;

  2358.             info.numSamples = samplesPerBlock;

  2359.             info.startSample = 0;

  2360.             sourceBuffer.clear();

  2361. 

  2362.             source->getNextAudioBlock (info);

  2363.         }

  2364. 

  2365.         zeromem (buffer, bytesPerBlock);

  2366. 

  2367.         AudioDataConverters::convertFloatToInt16LE (sourceBuffer.getSampleData (0, 0),

  2368.                                                     buffer, samplesPerBlock, 4);

  2369. 

  2370.         AudioDataConverters::convertFloatToInt16LE (sourceBuffer.getSampleData (1, 0),

  2371.                                                     buffer + 2, samplesPerBlock, 4);

  2372. 

  2373.         hr = info->redbook->AddAudioTrackBlocks (buffer, bytesPerBlock);

  2374. 

  2375.         if (hr != S_OK)

  2376.             ok = false;

  2377. 

  2378.         samplesDone += samplesPerBlock;

  2379. 

  2380.         if (samplesDone >= numSamples)

  2381.             break;

  2382.     }

  2383. 

  2384.     juce_free (buffer);

  2385. 

  2386.     hr = info->redbook->CloseAudioTrack();

  2387. 

  2388.     delete source;

  2389. 

  2390.     return ok && hr == S_OK;

  2391. }

  2392. 

  2393. #endif