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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 | /* * Apple Peripheral System Controller (PSC) * * The PSC is used on the AV Macs to control IO functions not handled * by the VIAs (Ethernet, DSP, SCC, Sound). This includes nine DMA * channels. * * The first seven DMA channels appear to be "one-shot" and are actually * sets of two channels; one member is active while the other is being * configured, and then you flip the active member and start all over again. * The one-shot channels are grouped together and are: * * 1. SCSI * 2. Ethernet Read * 3. Ethernet Write * 4. Floppy Disk Controller * 5. SCC Channel A Receive * 6. SCC Channel B Receive * 7. SCC Channel A Transmit * * The remaining two channels are handled somewhat differently. They appear * to be closely tied and share one set of registers. They also seem to run * continuously, although how you keep the buffer filled in this scenario is * not understood as there seems to be only one input and one output buffer * pointer. * * Much of this was extrapolated from what was known about the Ethernet * registers and subsequently confirmed using MacsBug (ie by pinging the * machine with easy-to-find patterns and looking for them in the DMA * buffers, or by sending a file over the serial ports and finding the * file in the buffers.) * * 1999-05-25 (jmt) */ #define PSC_BASE (0x50F31000) /* * The IER/IFR registers work like the VIA, except that it has 4 * of them each on different interrupt levels, and each register * set only seems to handle four interrupts instead of seven. * * To access a particular set of registers, add 0xn0 to the base * where n = 3,4,5 or 6. */ #define pIFRbase 0x100 #define pIERbase 0x104 /* * One-shot DMA control registers */ #define PSC_CTL_BASE 0xC00 #define PSC_SCSI_CTL 0xC00 #define PSC_ENETRD_CTL 0xC10 #define PSC_ENETWR_CTL 0xC20 #define PSC_FDC_CTL 0xC30 #define PSC_SCCA_CTL 0xC40 #define PSC_SCCB_CTL 0xC50 #define PSC_SCCATX_CTL 0xC60 /* * DMA channels. Add +0x10 for the second channel in the set. * You're supposed to use one channel while the other runs and * then flip channels and do the whole thing again. */ #define PSC_ADDR_BASE 0x1000 #define PSC_LEN_BASE 0x1004 #define PSC_CMD_BASE 0x1008 #define PSC_SCSI_ADDR 0x1000 /* confirmed */ #define PSC_SCSI_LEN 0x1004 /* confirmed */ #define PSC_SCSI_CMD 0x1008 /* confirmed */ #define PSC_ENETRD_ADDR 0x1020 /* confirmed */ #define PSC_ENETRD_LEN 0x1024 /* confirmed */ #define PSC_ENETRD_CMD 0x1028 /* confirmed */ #define PSC_ENETWR_ADDR 0x1040 /* confirmed */ #define PSC_ENETWR_LEN 0x1044 /* confirmed */ #define PSC_ENETWR_CMD 0x1048 /* confirmed */ #define PSC_FDC_ADDR 0x1060 /* strongly suspected */ #define PSC_FDC_LEN 0x1064 /* strongly suspected */ #define PSC_FDC_CMD 0x1068 /* strongly suspected */ #define PSC_SCCA_ADDR 0x1080 /* confirmed */ #define PSC_SCCA_LEN 0x1084 /* confirmed */ #define PSC_SCCA_CMD 0x1088 /* confirmed */ #define PSC_SCCB_ADDR 0x10A0 /* confirmed */ #define PSC_SCCB_LEN 0x10A4 /* confirmed */ #define PSC_SCCB_CMD 0x10A8 /* confirmed */ #define PSC_SCCATX_ADDR 0x10C0 /* confirmed */ #define PSC_SCCATX_LEN 0x10C4 /* confirmed */ #define PSC_SCCATX_CMD 0x10C8 /* confirmed */ /* * Free-running DMA registers. The only part known for sure are the bits in * the control register, the buffer addresses and the buffer length. Everything * else is anybody's guess. * * These registers seem to be mirrored every thirty-two bytes up until offset * 0x300. It's safe to assume then that a new set of registers starts there. */ #define PSC_SND_CTL 0x200 /* * [ 16-bit ] * Sound (Singer?) control register. * * bit 0 : ???? * bit 1 : ???? * bit 2 : Set to one to enable sound * output. Possibly a mute flag. * bit 3 : ???? * bit 4 : ???? * bit 5 : ???? * bit 6 : Set to one to enable pass-thru * audio. In this mode the audio data * seems to appear in both the input * buffer and the output buffer. * bit 7 : Set to one to activate the * sound input DMA or zero to * disable it. * bit 8 : Set to one to activate the * sound output DMA or zero to * disable it. * bit 9 : \ * bit 11 : | * These two bits control the sample * rate. Usually set to binary 10 and * MacOS 8.0 says I'm at 48 KHz. Using * a binary value of 01 makes things * sound about 1/2 speed (24 KHz?) and * binary 00 is slower still (22 KHz?) * * Setting this to 0x0000 is a good way to * kill all DMA at boot time so that the * PSC won't overwrite the kernel image * with sound data. */ /* * 0x0202 - 0x0203 is unused. Writing there * seems to clobber the control register. */ #define PSC_SND_SOURCE 0x204 /* * [ 32-bit ] * Controls input source and volume: * * bits 12-15 : input source volume, 0 - F * bits 16-19 : unknown, always 0x5 * bits 20-23 : input source selection: * 0x3 = CD Audio * 0x4 = External Audio * * The volume is definately not the general * output volume as it doesn't affect the * alert sound volume. */ #define PSC_SND_STATUS1 0x208 /* * [ 32-bit ] * Appears to be a read-only status register. * The usual value is 0x00400002. */ #define PSC_SND_HUH3 0x20C /* * [ 16-bit ] * Unknown 16-bit value, always 0x0000. */ #define PSC_SND_BITS2GO 0x20E /* * [ 16-bit ] * Counts down to zero from some constant * value. The value appears to be the * number of _bits_ remaining before the * buffer is full, which would make sense * since Apple's docs say the sound DMA * channels are 1 bit wide. */ #define PSC_SND_INADDR 0x210 /* * [ 32-bit ] * Address of the sound input DMA buffer */ #define PSC_SND_OUTADDR 0x214 /* * [ 32-bit ] * Address of the sound output DMA buffer */ #define PSC_SND_LEN 0x218 /* * [ 16-bit ] * Length of both buffers in eight-byte units. */ #define PSC_SND_HUH4 0x21A /* * [ 16-bit ] * Unknown, always 0x0000. */ #define PSC_SND_STATUS2 0x21C /* * [ 16-bit ] * Appears to e a read-only status register. * The usual value is 0x0200. */ #define PSC_SND_HUH5 0x21E /* * [ 16-bit ] * Unknown, always 0x0000. */ #ifndef __ASSEMBLY__ extern volatile __u8 *psc; extern int psc_present; /* * Access functions */ extern inline void psc_write_byte(int offset, __u8 data) { *((volatile __u8 *)(psc + offset)) = data; } extern inline void psc_write_word(int offset, __u16 data) { *((volatile __u16 *)(psc + offset)) = data; } extern inline void psc_write_long(int offset, __u32 data) { *((volatile __u32 *)(psc + offset)) = data; } extern inline u8 psc_read_byte(int offset) { return *((volatile __u8 *)(psc + offset)); } extern inline u16 psc_read_word(int offset) { return *((volatile __u16 *)(psc + offset)); } extern inline u32 psc_read_long(int offset) { return *((volatile __u32 *)(psc + offset)); } #endif /* __ASSEMBLY__ */ |