/[dynamips]/trunk/dev_gt.c
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Revision 7 - (show annotations)
Sat Oct 6 16:23:47 2007 UTC (16 years, 5 months ago) by dpavlin
Original Path: upstream/dynamips-0.2.7-RC1/dev_gt.c
File MIME type: text/plain
File size: 57229 byte(s)
dynamips-0.2.7-RC1

1 /*
2 * Cisco router simulation platform.
3 * Copyright (c) 2005,2006 Christophe Fillot (cf@utc.fr)
4 *
5 * Galileo GT64010/GT64120A/GT96100A system controller.
6 *
7 * The DMA stuff is not complete, only "normal" transfers are working
8 * (source and destination addresses incrementing).
9 *
10 * Also, these transfers are "instantaneous" from a CPU point-of-view: when
11 * a channel is enabled, the transfer is immediately done. So, this is not
12 * very realistic.
13 */
14
15 #include <stdio.h>
16 #include <stdlib.h>
17 #include <string.h>
18
19 #include "utils.h"
20 #include "net.h"
21 #include "cpu.h"
22 #include "vm.h"
23 #include "dynamips.h"
24 #include "memory.h"
25 #include "device.h"
26 #include "net_io.h"
27 #include "ptask.h"
28 #include "dev_gt.h"
29
30 /* Debugging flags */
31 #define DEBUG_UNKNOWN 0
32 #define DEBUG_DMA 0
33 #define DEBUG_MII 0
34 #define DEBUG_ETH_TX 0
35 #define DEBUG_ETH_RX 0
36 #define DEBUG_ETH_HASH 0
37
38 /* PCI identification */
39 #define PCI_VENDOR_GALILEO 0x11ab /* Galileo Technology */
40 #define PCI_PRODUCT_GALILEO_GT64010 0x0146 /* GT-64010 */
41 #define PCI_PRODUCT_GALILEO_GT64011 0x4146 /* GT-64011 */
42 #define PCI_PRODUCT_GALILEO_GT64120 0x4620 /* GT-64120 */
43 #define PCI_PRODUCT_GALILEO_GT96100 0x9653 /* GT-96100 */
44
45 /* === Global definitions === */
46
47 /* Interrupt High Cause Register */
48 #define GT_IHCR_ETH0_SUM 0x00000001
49 #define GT_IHCR_ETH1_SUM 0x00000002
50 #define GT_IHCR_SDMA_SUM 0x00000010
51
52 /* Serial Cause Register */
53 #define GT_SCR_ETH0_SUM 0x00000001
54 #define GT_SCR_ETH1_SUM 0x00000002
55 #define GT_SCR_SDMA_SUM 0x00000010
56
57 /* === DMA definitions === */
58 #define GT_DMA_CHANNELS 4
59
60 #define GT_DMA_FLYBY_ENABLE 0x00000001 /* FlyBy Enable */
61 #define GT_DMA_FLYBY_RDWR 0x00000002 /* SDRAM Read/Write (FlyBy) */
62 #define GT_DMA_SRC_DIR 0x0000000c /* Source Direction */
63 #define GT_DMA_DST_DIR 0x00000030 /* Destination Direction */
64 #define GT_DMA_DATA_LIMIT 0x000001c0 /* Data Transfer Limit */
65 #define GT_DMA_CHAIN_MODE 0x00000200 /* Chained Mode */
66 #define GT_DMA_INT_MODE 0x00000400 /* Interrupt Mode */
67 #define GT_DMA_TRANS_MODE 0x00000800 /* Transfer Mode */
68 #define GT_DMA_CHAN_ENABLE 0x00001000 /* Channel Enable */
69 #define GT_DMA_FETCH_NEXT 0x00002000 /* Fetch Next Record */
70 #define GT_DMA_ACT_STATUS 0x00004000 /* DMA Activity Status */
71 #define GT_DMA_SDA 0x00008000 /* Source/Destination Alignment */
72 #define GT_DMA_MDREQ 0x00010000 /* Mask DMA Requests */
73 #define GT_DMA_CDE 0x00020000 /* Close Descriptor Enable */
74 #define GT_DMA_EOTE 0x00040000 /* End-of-Transfer (EOT) Enable */
75 #define GT_DMA_EOTIE 0x00080000 /* EOT Interrupt Enable */
76 #define GT_DMA_ABORT 0x00100000 /* Abort DMA Transfer */
77 #define GT_DMA_SLP 0x00600000 /* Override Source Address */
78 #define GT_DMA_DLP 0x01800000 /* Override Dest Address */
79 #define GT_DMA_RLP 0x06000000 /* Override Record Address */
80 #define GT_DMA_REQ_SRC 0x10000000 /* DMA Request Source */
81
82 /* Galileo DMA channel */
83 struct dma_channel {
84 m_uint32_t byte_count;
85 m_uint32_t src_addr;
86 m_uint32_t dst_addr;
87 m_uint32_t cdptr;
88 m_uint32_t nrptr;
89 m_uint32_t ctrl;
90 };
91
92 /* === Ethernet definitions === */
93 #define GT_ETH_PORTS 2
94 #define GT_MAX_PKT_SIZE 2048
95
96 /* SMI register */
97 #define GT_SMIR_DATA_MASK 0x0000FFFF
98 #define GT_SMIR_PHYAD_MASK 0x001F0000 /* PHY Device Address */
99 #define GT_SMIR_PHYAD_SHIFT 16
100 #define GT_SMIR_REGAD_MASK 0x03e00000 /* PHY Device Register Address */
101 #define GT_SMIR_REGAD_SHIFT 21
102 #define GT_SMIR_OPCODE_MASK 0x04000000 /* Opcode (0: write, 1: read) */
103 #define GT_SMIR_OPCODE_READ 0x04000000
104 #define GT_SMIR_RVALID_FLAG 0x08000000 /* Read Valid */
105 #define GT_SMIR_BUSY_FLAG 0x10000000 /* Busy: 1=op in progress */
106
107 /* PCR: Port Configuration Register */
108 #define GT_PCR_PM 0x00000001 /* Promiscuous mode */
109 #define GT_PCR_RBM 0x00000002 /* Reject broadcast mode */
110 #define GT_PCR_PBF 0x00000004 /* Pass bad frames */
111 #define GT_PCR_EN 0x00000080 /* Port Enabled/Disabled */
112 #define GT_PCR_LPBK 0x00000300 /* Loopback mode */
113 #define GT_PCR_FC 0x00000400 /* Force collision */
114 #define GT_PCR_HS 0x00001000 /* Hash size */
115 #define GT_PCR_HM 0x00002000 /* Hash mode */
116 #define GT_PCR_HDM 0x00004000 /* Hash default mode */
117 #define GT_PCR_HD 0x00008000 /* Duplex Mode */
118 #define GT_PCR_ISL 0x70000000 /* ISL enabled (0x06) */
119 #define GT_PCR_ACCS 0x80000000 /* Accelerate Slot Time */
120
121 /* PCXR: Port Configuration Extend Register */
122 #define GT_PCXR_IGMP 0x00000001 /* IGMP packet capture */
123 #define GT_PCXR_SPAN 0x00000002 /* BPDU packet capture */
124 #define GT_PCXR_PAR 0x00000004 /* Partition Enable */
125 #define GT_PCXR_PRIOTX 0x00000038 /* Priority weight for TX */
126 #define GT_PCXR_PRIORX 0x000000C0 /* Priority weight for RX */
127 #define GT_PCXR_PRIORX_OV 0x00000100 /* Prio RX override */
128 #define GT_PCXR_DPLX_EN 0x00000200 /* Autoneg for Duplex */
129 #define GT_PCXR_FCTL_EN 0x00000400 /* Autoneg for 802.3x */
130 #define GT_PCXR_FLP 0x00000800 /* Force Link Pass */
131 #define GT_PCXR_FCTL 0x00001000 /* Flow Control Mode */
132 #define GT_PCXR_MFL 0x0000C000 /* Maximum Frame Length */
133 #define GT_PCXR_MIB_CLR_MODE 0x00010000 /* MIB counters clear mode */
134 #define GT_PCXR_SPEED 0x00040000 /* Port Speed */
135 #define GT_PCXR_SPEED_EN 0x00080000 /* Autoneg for Speed */
136 #define GT_PCXR_RMII_EN 0x00100000 /* RMII Enable */
137 #define GT_PCXR_DSCP_EN 0x00200000 /* DSCP decoding enable */
138
139 /* PCMR: Port Command Register */
140 #define GT_PCMR_FJ 0x00008000 /* Force Jam / Flow Control */
141
142 /* PSR: Port Status Register */
143 #define GT_PSR_SPEED 0x00000001 /* Speed: 10/100 Mb/s (100=>1)*/
144 #define GT_PSR_DUPLEX 0x00000002 /* Duplex (1: full) */
145 #define GT_PSR_FCTL 0x00000004 /* Flow Control Mode */
146 #define GT_PSR_LINK 0x00000008 /* Link Up/Down */
147 #define GT_PSR_PAUSE 0x00000010 /* Flow-control disabled state */
148 #define GT_PSR_TXLOW 0x00000020 /* TX Low priority status */
149 #define GT_PSR_TXHIGH 0x00000040 /* TX High priority status */
150 #define GT_PSR_TXINP 0x00000080 /* TX in Progress */
151
152 /* SDCR: SDMA Configuration Register */
153 #define GT_SDCR_RC 0x0000003c /* Retransmit count */
154 #define GT_SDCR_BLMR 0x00000040 /* Big/Little Endian RX mode */
155 #define GT_SDCR_BLMT 0x00000080 /* Big/Litlle Endian TX mode */
156 #define GT_SDCR_POVR 0x00000100 /* PCI override */
157 #define GT_SDCR_RIFB 0x00000200 /* RX IRQ on frame boundary */
158 #define GT_SDCR_BSZ 0x00003000 /* Burst size */
159
160 /* SDCMR: SDMA Command Register */
161 #define GT_SDCMR_ERD 0x00000080 /* Enable RX DMA */
162 #define GT_SDCMR_AR 0x00008000 /* Abort Receive */
163 #define GT_SDCMR_STDH 0x00010000 /* Stop TX High */
164 #define GT_SDCMR_STDL 0x00020000 /* Stop TX Low */
165 #define GT_SDCMR_TXDH 0x00800000 /* Start TX High */
166 #define GT_SDCMR_TXDL 0x01000000 /* Start TX Low */
167 #define GT_SDCMR_AT 0x80000000 /* Abort Transmit */
168
169 /* ICR: Interrupt Cause Register */
170 #define GT_ICR_RXBUF 0x00000001 /* RX Buffer returned to host */
171 #define GT_ICR_TXBUFH 0x00000004 /* TX Buffer High */
172 #define GT_ICR_TXBUFL 0x00000008 /* TX Buffer Low */
173 #define GT_ICR_TXENDH 0x00000040 /* TX End High */
174 #define GT_ICR_TXENDL 0x00000080 /* TX End Low */
175 #define GT_ICR_RXERR 0x00000100 /* RX Error */
176 #define GT_ICR_TXERRH 0x00000400 /* TX Error High */
177 #define GT_ICR_TXERRL 0x00000800 /* TX Error Low */
178 #define GT_ICR_RXOVR 0x00001000 /* RX Overrun */
179 #define GT_ICR_TXUDR 0x00002000 /* TX Underrun */
180 #define GT_ICR_RXBUFQ0 0x00010000 /* RX Buffer in Prio Queue 0 */
181 #define GT_ICR_RXBUFQ1 0x00020000 /* RX Buffer in Prio Queue 1 */
182 #define GT_ICR_RXBUFQ2 0x00040000 /* RX Buffer in Prio Queue 2 */
183 #define GT_ICR_RXBUFQ3 0x00080000 /* RX Buffer in Prio Queue 3 */
184 #define GT_ICR_RXERRQ0 0x00010000 /* RX Error in Prio Queue 0 */
185 #define GT_ICR_RXERRQ1 0x00020000 /* RX Error in Prio Queue 1 */
186 #define GT_ICR_RXERRQ2 0x00040000 /* RX Error in Prio Queue 2 */
187 #define GT_ICR_RXERRQ3 0x00080000 /* RX Error in Prio Queue 3 */
188 #define GT_ICR_MII_STC 0x10000000 /* MII PHY Status Change */
189 #define GT_ICR_SMI_DONE 0x20000000 /* SMI Command Done */
190 #define GT_ICR_INT_SUM 0x80000000 /* Ethernet Interrupt Summary */
191 #define GT_ICR_MASK 0x7FFFFFFF
192
193 /* Ethernet hash entry */
194 #define GT_HTE_VALID 0x00000001 /* Valid entry */
195 #define GT_HTE_SKIP 0x00000002 /* Skip entry in a chain */
196 #define GT_HTE_RD 0x00000004 /* 0: Discard, 1: Receive */
197 #define GT_HTE_ADDR_MASK 0x7fffffffffff8ULL
198
199 #define GT_HTE_HOPNUM 12 /* Hash Table Hop Number */
200
201 enum {
202 GT_HTLOOKUP_MISS,
203 GT_HTLOOKUP_MATCH,
204 GT_HTLOOKUP_HOP_EXCEEDED,
205 };
206
207 /* TX Descriptor */
208 #define GT_TXDESC_OWN 0x80000000 /* Ownership */
209 #define GT_TXDESC_AM 0x40000000 /* Auto-mode */
210 #define GT_TXDESC_EI 0x00800000 /* Enable Interrupt */
211 #define GT_TXDESC_GC 0x00400000 /* Generate CRC */
212 #define GT_TXDESC_P 0x00040000 /* Padding */
213 #define GT_TXDESC_F 0x00020000 /* First buffer of packet */
214 #define GT_TXDESC_L 0x00010000 /* Last buffer of packet */
215 #define GT_TXDESC_ES 0x00008000 /* Error Summary */
216 #define GT_TXDESC_RC 0x00003c00 /* Retransmit Count */
217 #define GT_TXDESC_COL 0x00000200 /* Collision */
218 #define GT_TXDESC_RL 0x00000100 /* Retransmit Limit Error */
219 #define GT_TXDESC_UR 0x00000040 /* Underrun Error */
220 #define GT_TXDESC_LC 0x00000020 /* Late Collision Error */
221
222 #define GT_TXDESC_BC_MASK 0xFFFF0000 /* Number of bytes to transmit */
223 #define GT_TXDESC_BC_SHIFT 16
224
225 /* RX Descriptor */
226 #define GT_RXDESC_OWN 0x80000000 /* Ownership */
227 #define GT_RXDESC_AM 0x40000000 /* Auto-mode */
228 #define GT_RXDESC_EI 0x00800000 /* Enable Interrupt */
229 #define GT_RXDESC_F 0x00020000 /* First buffer of packet */
230 #define GT_RXDESC_L 0x00010000 /* Last buffer of packet */
231 #define GT_RXDESC_ES 0x00008000 /* Error Summary */
232 #define GT_RXDESC_IGMP 0x00004000 /* IGMP packet detected */
233 #define GT_RXDESC_HE 0x00002000 /* Hash Table Expired */
234 #define GT_RXDESC_M 0x00001000 /* Missed Frame */
235 #define GT_RXDESC_FT 0x00000800 /* Frame Type (802.3/Ethernet) */
236 #define GT_RXDESC_SF 0x00000100 /* Short Frame Error */
237 #define GT_RXDESC_MFL 0x00000080 /* Maximum Frame Length Error */
238 #define GT_RXDESC_OR 0x00000040 /* Overrun Error */
239 #define GT_RXDESC_COL 0x00000010 /* Collision */
240 #define GT_RXDESC_CE 0x00000001 /* CRC Error */
241
242 #define GT_RXDESC_BC_MASK 0x0000FFFF /* Byte count */
243 #define GT_RXDESC_BS_MASK 0xFFFF0000 /* Buffer size */
244 #define GT_RXDESC_BS_SHIFT 16
245
246 /* RX/TX descriptor */
247 struct eth_desc {
248 m_uint32_t buf_size;
249 m_uint32_t cmd_stat;
250 m_uint32_t next_ptr;
251 m_uint32_t buf_ptr;
252 };
253
254 /* Galileo Ethernet port */
255 struct eth_port {
256 netio_desc_t *nio;
257
258 /* First and Current RX descriptors (4 queues) */
259 m_uint32_t rx_start[4],rx_current[4];
260
261 /* Current TX descriptors (2 queues) */
262 m_uint32_t tx_current[2];
263
264 /* Port registers */
265 m_uint32_t pcr,pcxr,pcmr,psr;
266
267 /* SDMA registers */
268 m_uint32_t sdcr,sdcmr;
269
270 /* Interrupt register */
271 m_uint32_t icr,imr;
272
273 /* Hash Table pointer */
274 m_uint32_t ht_addr;
275
276 /* Ethernet MIB counters */
277 m_uint32_t rx_bytes,tx_bytes,rx_frames,tx_frames;
278 };
279
280 /* Galileo GT64xxx/GT96xxx system controller */
281 struct gt_data {
282 char *name;
283 vm_obj_t vm_obj;
284 struct vdevice dev;
285 struct pci_device *pci_dev;
286 vm_instance_t *vm;
287
288 struct pci_bus *bus[2];
289 struct dma_channel dma[GT_DMA_CHANNELS];
290 m_uint32_t int_cause_reg;
291 m_uint32_t int_mask_reg;
292
293 /* Ethernet ports (GT-96100) */
294 u_int eth_irq;
295 ptask_id_t eth_tx_tid;
296 struct eth_port eth_ports[GT_ETH_PORTS];
297 m_uint32_t smi_reg;
298 m_uint16_t mii_regs[32][32];
299 };
300
301 /* Log a GT message */
302 #define GT_LOG(d,msg...) vm_log((d)->vm,(d)->name,msg)
303
304 /* Update the interrupt status */
305 static void gt_update_irq_status(struct gt_data *gt_data)
306 {
307 if (gt_data->pci_dev) {
308 if (gt_data->int_cause_reg & gt_data->int_mask_reg)
309 pci_dev_trigger_irq(gt_data->vm,gt_data->pci_dev);
310 else
311 pci_dev_clear_irq(gt_data->vm,gt_data->pci_dev);
312 }
313 }
314
315 /* Fetch a DMA record (chained mode) */
316 static void gt_dma_fetch_rec(vm_instance_t *vm,struct dma_channel *channel)
317 {
318 m_uint32_t ptr;
319
320 #if DEBUG_DMA
321 vm_log(vm,"GT_DMA","fetching record at address 0x%x\n",channel->nrptr);
322 #endif
323
324 /* fetch the record from RAM */
325 ptr = channel->nrptr;
326 channel->byte_count = swap32(physmem_copy_u32_from_vm(vm,ptr));
327 channel->src_addr = swap32(physmem_copy_u32_from_vm(vm,ptr+0x04));
328 channel->dst_addr = swap32(physmem_copy_u32_from_vm(vm,ptr+0x08));
329 channel->nrptr = swap32(physmem_copy_u32_from_vm(vm,ptr+0x0c));
330
331 /* clear the "fetch next record bit" */
332 channel->ctrl &= ~GT_DMA_FETCH_NEXT;
333 }
334
335 /* Handle control register of a DMA channel */
336 static void gt_dma_handle_ctrl(struct gt_data *gt_data,int chan_id)
337 {
338 struct dma_channel *channel = &gt_data->dma[chan_id];
339 vm_instance_t *vm = gt_data->vm;
340 int done;
341
342 if (channel->ctrl & GT_DMA_FETCH_NEXT) {
343 if (channel->nrptr == 0) {
344 vm_log(vm,"GT_DMA","trying to load a NULL DMA record...\n");
345 return;
346 }
347
348 gt_dma_fetch_rec(vm,channel);
349 }
350
351 if (channel->ctrl & GT_DMA_CHAN_ENABLE)
352 {
353 do {
354 done = TRUE;
355
356 #if DEBUG_DMA
357 vm_log(vm,"GT_DMA",
358 "starting transfer from 0x%x to 0x%x (size=%u bytes)\n",
359 channel->src_addr,channel->dst_addr,
360 channel->byte_count & 0xFFFF);
361 #endif
362 physmem_dma_transfer(vm,channel->src_addr,channel->dst_addr,
363 channel->byte_count & 0xFFFF);
364
365 /* chained mode */
366 if (!(channel->ctrl & GT_DMA_CHAIN_MODE)) {
367 if (channel->nrptr) {
368 gt_dma_fetch_rec(vm,channel);
369 done = FALSE;
370 }
371 }
372 }while(!done);
373
374 #if DEBUG_DMA
375 vm_log(vm,"GT_DMA","finished transfer.\n");
376 #endif
377 /* Trigger DMA interrupt */
378 gt_data->int_cause_reg |= 1 << (4 + chan_id);
379 gt_update_irq_status(gt_data);
380 }
381 }
382
383 #define DMA_REG(ch,reg_name) \
384 if (op_type == MTS_WRITE) \
385 gt_data->dma[ch].reg_name = swap32(*data); \
386 else \
387 *data = swap32(gt_data->dma[ch].reg_name);
388
389 /* Handle a DMA channel */
390 static int gt_dma_access(cpu_gen_t *cpu,struct vdevice *dev,
391 m_uint32_t offset,u_int op_size,u_int op_type,
392 m_uint64_t *data)
393 {
394 struct gt_data *gt_data = dev->priv_data;
395
396 switch(offset) {
397 /* DMA Source Address */
398 case 0x810: DMA_REG(0,src_addr); return(1);
399 case 0x814: DMA_REG(1,src_addr); return(1);
400 case 0x818: DMA_REG(2,src_addr); return(1);
401 case 0x81c: DMA_REG(3,src_addr); return(1);
402
403 /* DMA Destination Address */
404 case 0x820: DMA_REG(0,dst_addr); return(1);
405 case 0x824: DMA_REG(1,dst_addr); return(1);
406 case 0x828: DMA_REG(2,dst_addr); return(1);
407 case 0x82c: DMA_REG(3,dst_addr); return(1);
408
409 /* DMA Next Record Pointer */
410 case 0x830:
411 gt_data->dma[0].cdptr = *data;
412 DMA_REG(0,nrptr);
413 return(1);
414
415 case 0x834:
416 gt_data->dma[1].cdptr = *data;
417 DMA_REG(1,nrptr);
418 return(1);
419
420 case 0x838:
421 gt_data->dma[2].cdptr = *data;
422 DMA_REG(2,nrptr);
423 return(1);
424
425 case 0x83c:
426 gt_data->dma[3].cdptr = *data;
427 DMA_REG(3,nrptr);
428 return(1);
429
430 /* DMA Channel Control */
431 case 0x840:
432 DMA_REG(0,ctrl);
433 if (op_type == MTS_WRITE)
434 gt_dma_handle_ctrl(gt_data,0);
435 return(1);
436
437 case 0x844:
438 DMA_REG(1,ctrl);
439 if (op_type == MTS_WRITE)
440 gt_dma_handle_ctrl(gt_data,1);
441 return(1);
442
443 case 0x848:
444 DMA_REG(2,ctrl);
445 if (op_type == MTS_WRITE)
446 gt_dma_handle_ctrl(gt_data,2);
447 return(1);
448
449 case 0x84c:
450 DMA_REG(3,ctrl);
451 if (op_type == MTS_WRITE)
452 gt_dma_handle_ctrl(gt_data,3);
453 return(1);
454 }
455
456 return(0);
457 }
458
459 /*
460 * dev_gt64010_access()
461 */
462 void *dev_gt64010_access(cpu_gen_t *cpu,struct vdevice *dev,m_uint32_t offset,
463 u_int op_size,u_int op_type,m_uint64_t *data)
464 {
465 struct gt_data *gt_data = dev->priv_data;
466
467 if (op_type == MTS_READ)
468 *data = 0;
469
470 if (gt_dma_access(cpu,dev,offset,op_size,op_type,data) != 0)
471 return NULL;
472
473 switch(offset) {
474 /* ===== DRAM Settings (completely faked, 128 Mb) ===== */
475 case 0x008: /* ras10_low */
476 if (op_type == MTS_READ)
477 *data = swap32(0x000);
478 break;
479 case 0x010: /* ras10_high */
480 if (op_type == MTS_READ)
481 *data = swap32(0x7F);
482 break;
483 case 0x018: /* ras32_low */
484 if (op_type == MTS_READ)
485 *data = swap32(0x080);
486 break;
487 case 0x020: /* ras32_high */
488 if (op_type == MTS_READ)
489 *data = swap32(0x7F);
490 break;
491 case 0x400: /* ras0_low */
492 if (op_type == MTS_READ)
493 *data = swap32(0x00);
494 break;
495 case 0x404: /* ras0_high */
496 if (op_type == MTS_READ)
497 *data = swap32(0xFF);
498 break;
499 case 0x408: /* ras1_low */
500 if (op_type == MTS_READ)
501 *data = swap32(0x7F);
502 break;
503 case 0x40c: /* ras1_high */
504 if (op_type == MTS_READ)
505 *data = swap32(0x00);
506 break;
507 case 0x410: /* ras2_low */
508 if (op_type == MTS_READ)
509 *data = swap32(0x00);
510 break;
511 case 0x414: /* ras2_high */
512 if (op_type == MTS_READ)
513 *data = swap32(0xFF);
514 break;
515 case 0x418: /* ras3_low */
516 if (op_type == MTS_READ)
517 *data = swap32(0x7F);
518 break;
519 case 0x41c: /* ras3_high */
520 if (op_type == MTS_READ)
521 *data = swap32(0x00);
522 break;
523 case 0xc08: /* pci0_cs10 */
524 if (op_type == MTS_READ)
525 *data = swap32(0xFFF);
526 break;
527 case 0xc0c: /* pci0_cs32 */
528 if (op_type == MTS_READ)
529 *data = swap32(0xFFF);
530 break;
531
532 case 0xc00: /* pci_cmd */
533 if (op_type == MTS_READ)
534 *data = swap32(0x00008001);
535 break;
536
537 /* ===== Interrupt Cause Register ===== */
538 case 0xc18:
539 if (op_type == MTS_READ) {
540 *data = swap32(gt_data->int_cause_reg);
541 } else {
542 gt_data->int_cause_reg &= swap32(*data);
543 gt_update_irq_status(gt_data);
544 }
545 break;
546
547 /* ===== Interrupt Mask Register ===== */
548 case 0xc1c:
549 if (op_type == MTS_READ)
550 *data = swap32(gt_data->int_mask_reg);
551 else {
552 gt_data->int_mask_reg = swap32(*data);
553 gt_update_irq_status(gt_data);
554 }
555 break;
556
557 /* ===== PCI Configuration ===== */
558 case PCI_BUS_ADDR: /* pci configuration address (0xcf8) */
559 pci_dev_addr_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
560 break;
561
562 case PCI_BUS_DATA: /* pci data address (0xcfc) */
563 pci_dev_data_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
564 break;
565
566 #if DEBUG_UNKNOWN
567 default:
568 if (op_type == MTS_READ) {
569 cpu_log(cpu,"GT64010","read from addr 0x%x, pc=0x%llx\n",
570 offset,cpu_get_pc(cpu));
571 } else {
572 cpu_log(cpu,"GT64010","write to addr 0x%x, value=0x%llx, "
573 "pc=0x%llx\n",offset,*data,cpu_get_pc(cpu));
574 }
575 #endif
576 }
577
578 return NULL;
579 }
580
581 /*
582 * dev_gt64120_access()
583 */
584 void *dev_gt64120_access(cpu_gen_t *cpu,struct vdevice *dev,m_uint32_t offset,
585 u_int op_size,u_int op_type,m_uint64_t *data)
586 {
587 struct gt_data *gt_data = dev->priv_data;
588
589 if (op_type == MTS_READ)
590 *data = 0;
591
592 if (gt_dma_access(cpu,dev,offset,op_size,op_type,data) != 0)
593 return NULL;
594
595 switch(offset) {
596 case 0x008: /* ras10_low */
597 if (op_type == MTS_READ)
598 *data = swap32(0x000);
599 break;
600 case 0x010: /* ras10_high */
601 if (op_type == MTS_READ)
602 *data = swap32(0x7F);
603 break;
604 case 0x018: /* ras32_low */
605 if (op_type == MTS_READ)
606 *data = swap32(0x100);
607 break;
608 case 0x020: /* ras32_high */
609 if (op_type == MTS_READ)
610 *data = swap32(0x7F);
611 break;
612 case 0x400: /* ras0_low */
613 if (op_type == MTS_READ)
614 *data = swap32(0x00);
615 break;
616 case 0x404: /* ras0_high */
617 if (op_type == MTS_READ)
618 *data = swap32(0xFF);
619 break;
620 case 0x408: /* ras1_low */
621 if (op_type == MTS_READ)
622 *data = swap32(0x7F);
623 break;
624 case 0x40c: /* ras1_high */
625 if (op_type == MTS_READ)
626 *data = swap32(0x00);
627 break;
628 case 0x410: /* ras2_low */
629 if (op_type == MTS_READ)
630 *data = swap32(0x00);
631 break;
632 case 0x414: /* ras2_high */
633 if (op_type == MTS_READ)
634 *data = swap32(0xFF);
635 break;
636 case 0x418: /* ras3_low */
637 if (op_type == MTS_READ)
638 *data = swap32(0x7F);
639 break;
640 case 0x41c: /* ras3_high */
641 if (op_type == MTS_READ)
642 *data = swap32(0x00);
643 break;
644 case 0xc08: /* pci0_cs10 */
645 if (op_type == MTS_READ)
646 *data = swap32(0xFFF);
647 break;
648 case 0xc0c: /* pci0_cs32 */
649 if (op_type == MTS_READ)
650 *data = swap32(0xFFF);
651 break;
652
653 case 0xc00: /* pci_cmd */
654 if (op_type == MTS_READ)
655 *data = swap32(0x00008001);
656 break;
657
658 /* ===== Interrupt Cause Register ===== */
659 case 0xc18:
660 if (op_type == MTS_READ)
661 *data = swap32(gt_data->int_cause_reg);
662 else {
663 gt_data->int_cause_reg &= swap32(*data);
664 gt_update_irq_status(gt_data);
665 }
666 break;
667
668 /* ===== Interrupt Mask Register ===== */
669 case 0xc1c:
670 if (op_type == MTS_READ) {
671 *data = swap32(gt_data->int_mask_reg);
672 } else {
673 gt_data->int_mask_reg = swap32(*data);
674 gt_update_irq_status(gt_data);
675 }
676 break;
677
678 /* ===== PCI Bus 1 ===== */
679 case 0xcf0:
680 pci_dev_addr_handler(cpu,gt_data->bus[1],op_type,TRUE,data);
681 break;
682
683 case 0xcf4:
684 pci_dev_data_handler(cpu,gt_data->bus[1],op_type,TRUE,data);
685 break;
686
687 /* ===== PCI Bus 0 ===== */
688 case PCI_BUS_ADDR: /* pci configuration address (0xcf8) */
689 pci_dev_addr_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
690 break;
691
692 case PCI_BUS_DATA: /* pci data address (0xcfc) */
693 pci_dev_data_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
694 break;
695
696 #if DEBUG_UNKNOWN
697 default:
698 if (op_type == MTS_READ) {
699 cpu_log(cpu,"GT64120","read from addr 0x%x, pc=0x%llx\n",
700 offset,cpu_get_pc(cpu));
701 } else {
702 cpu_log(cpu,"GT64120","write to addr 0x%x, value=0x%llx, "
703 "pc=0x%llx\n",offset,*data,cpu_get_pc(cpu));
704 }
705 #endif
706 }
707
708 return NULL;
709 }
710
711 /* Update the Ethernet port interrupt status */
712 static void gt_eth_update_int_status(struct gt_data *d,struct eth_port *port)
713 {
714 if (port->icr & GT_ICR_MASK)
715 port->icr |= GT_ICR_INT_SUM;
716
717 if (port->icr & port->imr & GT_ICR_MASK)
718 vm_set_irq(d->vm,d->eth_irq);
719 }
720
721 /* Read a MII register */
722 static m_uint32_t gt_mii_read(struct gt_data *d)
723 {
724 m_uint8_t port,reg;
725 m_uint32_t res = 0;
726
727 port = (d->smi_reg & GT_SMIR_PHYAD_MASK) >> GT_SMIR_PHYAD_SHIFT;
728 reg = (d->smi_reg & GT_SMIR_REGAD_MASK) >> GT_SMIR_REGAD_SHIFT;
729
730 #if DEBUG_MII
731 GT_LOG(d,"MII: port 0x%4.4x, reg 0x%2.2x: reading.\n",port,reg);
732 #endif
733
734 if ((port < GT_ETH_PORTS) && (reg < 32)) {
735 res = d->mii_regs[port][reg];
736
737 switch(reg) {
738 case 0x00:
739 res &= ~0x8200; /* clear reset bit and autoneg restart */
740 break;
741 case 0x01:
742 #if 0
743 if (d->ports[port].nio && bcm5600_mii_port_status(d,port))
744 d->mii_output = 0x782C;
745 else
746 d->mii_output = 0;
747 #endif
748 res = 0x782c;
749 break;
750 case 0x02:
751 res = 0x40;
752 break;
753 case 0x03:
754 res = 0x61d4;
755 break;
756 case 0x04:
757 res = 0x1E1;
758 break;
759 case 0x05:
760 res = 0x41E1;
761 break;
762 default:
763 res = 0;
764 }
765 }
766
767 /* Mark the data as ready */
768 res |= GT_SMIR_RVALID_FLAG;
769
770 return(res);
771 }
772
773 /* Write a MII register */
774 static void gt_mii_write(struct gt_data *d)
775 {
776 m_uint8_t port,reg;
777 m_uint16_t isolation;
778
779 port = (d->smi_reg & GT_SMIR_PHYAD_MASK) >> GT_SMIR_PHYAD_SHIFT;
780 reg = (d->smi_reg & GT_SMIR_REGAD_MASK) >> GT_SMIR_REGAD_SHIFT;
781
782 if ((port < GT_ETH_PORTS) && (reg < 32))
783 {
784 #if DEBUG_MII
785 GT_LOG(d,"MII: port 0x%4.4x, reg 0x%2.2x: writing 0x%4.4x\n",
786 port,reg,d->smi_reg & GT_SMIR_DATA_MASK);
787 #endif
788
789 /* Check if PHY isolation status is changing */
790 if (reg == 0) {
791 isolation = (d->smi_reg ^ d->mii_regs[port][reg]) & 0x400;
792
793 if (isolation) {
794 #if DEBUG_MII
795 GT_LOG(d,"MII: port 0x%4.4x: generating IRQ\n",port);
796 #endif
797 d->eth_ports[port].icr |= GT_ICR_MII_STC;
798 gt_eth_update_int_status(d,&d->eth_ports[port]);
799 }
800 }
801
802 d->mii_regs[port][reg] = d->smi_reg & GT_SMIR_DATA_MASK;
803 }
804 }
805
806 /* Handle registers of Ethernet ports */
807 static int gt_eth_access(cpu_gen_t *cpu,struct vdevice *dev,
808 m_uint32_t offset,u_int op_size,u_int op_type,
809 m_uint64_t *data)
810 {
811 struct gt_data *d = dev->priv_data;
812 struct eth_port *port;
813 u_int port_id = 0;
814 u_int queue;
815
816 if ((offset < 0x80000) || (offset >= 0x90000))
817 return(FALSE);
818
819 if (op_type == MTS_WRITE)
820 *data = swap32(*data);
821
822 /* Detemine the Ethernet port */
823 if ((offset >= 0x84800) && (offset < 0x88800))
824 port_id = 0;
825
826 if ((offset >= 0x88800) && (offset < 0x8c800))
827 port_id = 1;
828
829 port = &d->eth_ports[port_id];
830
831 switch(offset) {
832 /* SMI register */
833 case 0x80810:
834 if (op_type == MTS_WRITE) {
835 d->smi_reg = *data;
836
837 if (!(d->smi_reg & GT_SMIR_OPCODE_READ))
838 gt_mii_write(d);
839 } else {
840 *data = 0;
841
842 if (d->smi_reg & GT_SMIR_OPCODE_READ)
843 *data = gt_mii_read(d);
844 }
845 break;
846
847 /* ICR: Interrupt Cause Register */
848 case 0x84850:
849 case 0x88850:
850 if (op_type == MTS_READ)
851 *data = port->icr;
852 else
853 port->icr &= *data;
854 break;
855
856 /* IMR: Interrupt Mask Register */
857 case 0x84858:
858 case 0x88858:
859 if (op_type == MTS_READ)
860 *data = port->imr;
861 else
862 port->imr = *data;
863 break;
864
865 /* PCR: Port Configuration Register */
866 case 0x84800:
867 case 0x88800:
868 if (op_type == MTS_READ)
869 *data = port->pcr;
870 else
871 port->pcr = *data;
872 break;
873
874 /* PCXR: Port Configuration Extend Register */
875 case 0x84808:
876 case 0x88808:
877 if (op_type == MTS_READ) {
878 *data = port->pcxr;
879 *data |= GT_PCXR_SPEED;
880 } else
881 port->pcxr = *data;
882 break;
883
884 /* PCMR: Port Command Register */
885 case 0x84810:
886 case 0x88810:
887 if (op_type == MTS_READ)
888 *data = port->pcmr;
889 else
890 port->pcmr = *data;
891 break;
892
893 /* Port Status Register */
894 case 0x84818:
895 case 0x88818:
896 if (op_type == MTS_READ)
897 *data = 0x0F;
898 break;
899
900 /* First RX descriptor */
901 case 0x84880:
902 case 0x88880:
903 case 0x84884:
904 case 0x88884:
905 case 0x84888:
906 case 0x88888:
907 case 0x8488C:
908 case 0x8888C:
909 queue = (offset >> 2) & 0x03;
910 if (op_type == MTS_READ)
911 *data = port->rx_start[queue];
912 else
913 port->rx_start[queue] = *data;
914 break;
915
916 /* Current RX descriptor */
917 case 0x848A0:
918 case 0x888A0:
919 case 0x848A4:
920 case 0x888A4:
921 case 0x848A8:
922 case 0x888A8:
923 case 0x848AC:
924 case 0x888AC:
925 queue = (offset >> 2) & 0x03;
926 if (op_type == MTS_READ)
927 *data = port->rx_current[queue];
928 else
929 port->rx_current[queue] = *data;
930 break;
931
932 /* Current TX descriptor */
933 case 0x848E0:
934 case 0x888E0:
935 case 0x848E4:
936 case 0x888E4:
937 queue = (offset >> 2) & 0x01;
938 if (op_type == MTS_READ)
939 *data = port->tx_current[queue];
940 else
941 port->tx_current[queue] = *data;
942 break;
943
944 /* Hash Table Pointer */
945 case 0x84828:
946 case 0x88828:
947 if (op_type == MTS_READ)
948 *data = port->ht_addr;
949 else
950 port->ht_addr = *data;
951 break;
952
953 /* SDCR: SDMA Configuration Register */
954 case 0x84840:
955 case 0x88840:
956 if (op_type == MTS_READ)
957 *data = port->sdcr;
958 else
959 port->sdcr = *data;
960 break;
961
962 /* SDCMR: SDMA Command Register */
963 case 0x84848:
964 case 0x88848:
965 if (op_type == MTS_WRITE) {
966 /* Start RX DMA */
967 if (*data & GT_SDCMR_ERD) {
968 port->sdcmr |= GT_SDCMR_ERD;
969 port->sdcmr &= ~GT_SDCMR_AR;
970 }
971
972 /* Abort RX DMA */
973 if (*data & GT_SDCMR_AR)
974 port->sdcmr &= ~GT_SDCMR_ERD;
975
976 /* Start TX High */
977 if (*data & GT_SDCMR_TXDH) {
978 port->sdcmr |= GT_SDCMR_TXDH;
979 port->sdcmr &= ~GT_SDCMR_STDH;
980 }
981
982 /* Start TX Low */
983 if (*data & GT_SDCMR_TXDL) {
984 port->sdcmr |= GT_SDCMR_TXDL;
985 port->sdcmr &= ~GT_SDCMR_STDL;
986 }
987
988 /* Stop TX High */
989 if (*data & GT_SDCMR_STDH) {
990 port->sdcmr &= ~GT_SDCMR_TXDH;
991 port->sdcmr |= GT_SDCMR_STDH;
992 }
993
994 /* Stop TX Low */
995 if (*data & GT_SDCMR_STDL) {
996 port->sdcmr &= ~GT_SDCMR_TXDL;
997 port->sdcmr |= GT_SDCMR_STDL;
998 }
999 } else {
1000 *data = port->sdcmr;
1001 }
1002 break;
1003
1004 case 0x85800:
1005 case 0x89800:
1006 if (op_type == MTS_READ) {
1007 *data = port->rx_bytes;
1008 port->rx_bytes = 0;
1009 }
1010 break;
1011
1012 case 0x85804:
1013 case 0x89804:
1014 if (op_type == MTS_READ) {
1015 *data = port->tx_bytes;
1016 port->tx_bytes = 0;
1017 }
1018 break;
1019
1020 case 0x85808:
1021 case 0x89808:
1022 if (op_type == MTS_READ) {
1023 *data = port->rx_frames;
1024 port->rx_frames = 0;
1025 }
1026 break;
1027
1028 case 0x8580C:
1029 case 0x8980C:
1030 if (op_type == MTS_READ) {
1031 *data = port->tx_frames;
1032 port->tx_frames = 0;
1033 }
1034 break;
1035
1036 #if DEBUG_UNKNOWN
1037 default:
1038 if (op_type == MTS_READ) {
1039 cpu_log(cpu,"GT96100/ETH",
1040 "read access to unknown register 0x%x, pc=0x%llx\n",
1041 offset,cpu_get_pc(cpu));
1042 } else {
1043 cpu_log(cpu,"GT96100/ETH",
1044 "write access to unknown register 0x%x, value=0x%llx, "
1045 "pc=0x%llx\n",offset,*data,cpu_get_pc(cpu));
1046 }
1047 #endif
1048 }
1049
1050 if (op_type == MTS_READ)
1051 *data = swap32(*data);
1052
1053 return(TRUE);
1054 }
1055
1056 /*
1057 * dev_gt96100_access()
1058 */
1059 void *dev_gt96100_access(cpu_gen_t *cpu,struct vdevice *dev,m_uint32_t offset,
1060 u_int op_size,u_int op_type,m_uint64_t *data)
1061 {
1062 struct gt_data *gt_data = dev->priv_data;
1063
1064 if (op_type == MTS_READ)
1065 *data = 0;
1066
1067 if (gt_dma_access(cpu,dev,offset,op_size,op_type,data) != 0)
1068 return NULL;
1069
1070 if (gt_eth_access(cpu,dev,offset,op_size,op_type,data) != 0)
1071 return NULL;
1072
1073 switch(offset) {
1074 /* Watchdog configuration register */
1075 case 0x101a80:
1076 break;
1077
1078 /* Watchdog value register */
1079 case 0x101a84:
1080 break;
1081
1082 case 0x008: /* ras10_low */
1083 if (op_type == MTS_READ)
1084 *data = swap32(0x000);
1085 break;
1086 case 0x010: /* ras10_high */
1087 if (op_type == MTS_READ)
1088 *data = swap32(0x7F);
1089 break;
1090 case 0x018: /* ras32_low */
1091 if (op_type == MTS_READ)
1092 *data = swap32(0x100);
1093 break;
1094 case 0x020: /* ras32_high */
1095 if (op_type == MTS_READ)
1096 *data = swap32(0x7F);
1097 break;
1098 case 0x400: /* ras0_low */
1099 if (op_type == MTS_READ)
1100 *data = swap32(0x00);
1101 break;
1102 case 0x404: /* ras0_high */
1103 if (op_type == MTS_READ)
1104 *data = swap32(0xFF);
1105 break;
1106 case 0x408: /* ras1_low */
1107 if (op_type == MTS_READ)
1108 *data = swap32(0x7F);
1109 break;
1110 case 0x40c: /* ras1_high */
1111 if (op_type == MTS_READ)
1112 *data = swap32(0x00);
1113 break;
1114 case 0x410: /* ras2_low */
1115 if (op_type == MTS_READ)
1116 *data = swap32(0x00);
1117 break;
1118 case 0x414: /* ras2_high */
1119 if (op_type == MTS_READ)
1120 *data = swap32(0xFF);
1121 break;
1122 case 0x418: /* ras3_low */
1123 if (op_type == MTS_READ)
1124 *data = swap32(0x7F);
1125 break;
1126 case 0x41c: /* ras3_high */
1127 if (op_type == MTS_READ)
1128 *data = swap32(0x00);
1129 break;
1130 case 0xc08: /* pci0_cs10 */
1131 if (op_type == MTS_READ)
1132 *data = swap32(0xFFF);
1133 break;
1134 case 0xc0c: /* pci0_cs32 */
1135 if (op_type == MTS_READ)
1136 *data = swap32(0xFFF);
1137 break;
1138
1139 case 0xc00: /* pci_cmd */
1140 if (op_type == MTS_READ)
1141 *data = swap32(0x00008001);
1142 break;
1143
1144 /* ===== Interrupt Main Cause Register ===== */
1145 case 0xc18:
1146 if (op_type == MTS_READ) {
1147 *data = gt_data->int_cause_reg;
1148
1149 /* TODO: signal Eth0/Eth1 */
1150 //*data |= (1 << 30) | (1 << 31) | 1;
1151
1152 *data = swap32(*data);
1153 } else {
1154 gt_data->int_cause_reg &= swap32(*data);
1155 gt_update_irq_status(gt_data);
1156 }
1157 break;
1158
1159 /* ===== Interrupt Mask Register ===== */
1160 case 0xc1c:
1161 if (op_type == MTS_READ) {
1162 *data = swap32(gt_data->int_mask_reg);
1163 } else {
1164 gt_data->int_mask_reg = swap32(*data);
1165 gt_update_irq_status(gt_data);
1166 }
1167 break;
1168
1169 /* ===== Interrupt High Cause Register ===== */
1170 case 0xc98:
1171 if (op_type == MTS_READ) {
1172 *data = 0;
1173
1174 /* interrupt on ethernet port 0 ? */
1175 if (gt_data->eth_ports[0].icr & GT_ICR_INT_SUM)
1176 *data |= GT_IHCR_ETH0_SUM;
1177
1178 /* interrupt on ethernet port 1 ? */
1179 if (gt_data->eth_ports[1].icr & GT_ICR_INT_SUM)
1180 *data |= GT_IHCR_ETH1_SUM;
1181
1182 *data = swap32(*data);
1183 }
1184 break;
1185
1186 /* Serial Cause Register */
1187 case 0x103a00:
1188 if (op_type == MTS_READ) {
1189 *data = 0;
1190
1191 /* interrupt on ethernet port 0 ? */
1192 if (gt_data->eth_ports[0].icr & GT_ICR_INT_SUM)
1193 *data |= GT_SCR_ETH0_SUM;
1194
1195 /* interrupt on ethernet port 1 ? */
1196 if (gt_data->eth_ports[1].icr & GT_ICR_INT_SUM)
1197 *data |= GT_SCR_ETH1_SUM;
1198
1199 *data = swap32(*data);
1200 }
1201 break;
1202
1203 /* ===== PCI Bus 1 ===== */
1204 case 0xcf0:
1205 pci_dev_addr_handler(cpu,gt_data->bus[1],op_type,TRUE,data);
1206 break;
1207
1208 case 0xcf4:
1209 pci_dev_data_handler(cpu,gt_data->bus[1],op_type,TRUE,data);
1210 break;
1211
1212 /* ===== PCI Bus 0 ===== */
1213 case PCI_BUS_ADDR: /* pci configuration address (0xcf8) */
1214 pci_dev_addr_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
1215 break;
1216
1217 case PCI_BUS_DATA: /* pci data address (0xcfc) */
1218 pci_dev_data_handler(cpu,gt_data->bus[0],op_type,TRUE,data);
1219 break;
1220
1221 #if DEBUG_UNKNOWN
1222 default:
1223 if (op_type == MTS_READ) {
1224 cpu_log(cpu,"GT96100","read from addr 0x%x, pc=0x%llx\n",
1225 offset,cpu_get_pc(cpu));
1226 } else {
1227 cpu_log(cpu,"GT96100","write to addr 0x%x, value=0x%llx, "
1228 "pc=0x%llx\n",offset,*data,cpu_get_pc(cpu));
1229 }
1230 #endif
1231 }
1232
1233 return NULL;
1234 }
1235
1236 /* Read an Ethernet descriptor */
1237 static void gt_eth_desc_read(struct gt_data *d,m_uint32_t addr,
1238 struct eth_desc *desc)
1239 {
1240 physmem_copy_from_vm(d->vm,desc,addr,sizeof(struct eth_desc));
1241
1242 /* byte-swapping */
1243 desc->cmd_stat = vmtoh32(desc->cmd_stat);
1244 desc->buf_size = vmtoh32(desc->buf_size);
1245 desc->next_ptr = vmtoh32(desc->next_ptr);
1246 desc->buf_ptr = vmtoh32(desc->buf_ptr);
1247 }
1248
1249 /* Write an Ethernet descriptor */
1250 static void gt_eth_desc_write(struct gt_data *d,m_uint32_t addr,
1251 struct eth_desc *desc)
1252 {
1253 struct eth_desc tmp;
1254
1255 /* byte-swapping */
1256 tmp.cmd_stat = vmtoh32(desc->cmd_stat);
1257 tmp.buf_size = vmtoh32(desc->buf_size);
1258 tmp.next_ptr = vmtoh32(desc->next_ptr);
1259 tmp.buf_ptr = vmtoh32(desc->buf_ptr);
1260
1261 physmem_copy_to_vm(d->vm,&tmp,addr,sizeof(struct eth_desc));
1262 }
1263
1264 /* Handle a TX queue (single packet) */
1265 static int gt_eth_handle_txqueue(struct gt_data *d,struct eth_port *port,
1266 int queue)
1267 {
1268 u_char pkt[GT_MAX_PKT_SIZE],*pkt_ptr;
1269 struct eth_desc txd0,ctxd,*ptxd;
1270 m_uint32_t tx_start,tx_current;
1271 m_uint32_t len,tot_len;
1272 int abort = FALSE;
1273
1274 /* Check if this TX queue is active */
1275 if ((queue == 0) && (port->sdcmr & GT_SDCMR_STDL))
1276 return(FALSE);
1277
1278 if ((queue == 1) && (port->sdcmr & GT_SDCMR_STDH))
1279 return(FALSE);
1280
1281 /* Copy the current txring descriptor */
1282 tx_start = tx_current = port->tx_current[queue];
1283
1284 if (!tx_start)
1285 goto done;
1286
1287 ptxd = &txd0;
1288 gt_eth_desc_read(d,tx_start,ptxd);
1289
1290 /* If we don't own the first descriptor, we cannot transmit */
1291 if (!(txd0.cmd_stat & GT_TXDESC_OWN))
1292 goto done;
1293
1294 /* Empty packet for now */
1295 pkt_ptr = pkt;
1296 tot_len = 0;
1297
1298 for(;;) {
1299 #if DEBUG_ETH_TX
1300 GT_LOG(d,"gt_eth_handle_txqueue: loop: "
1301 "cmd_stat=0x%x, buf_size=0x%x, next_ptr=0x%x, buf_ptr=0x%x\n",
1302 ptxd->cmd_stat,ptxd->buf_size,ptxd->next_ptr,ptxd->buf_ptr);
1303 #endif
1304
1305 if (!(ptxd->cmd_stat & GT_TXDESC_OWN)) {
1306 GT_LOG(d,"gt_eth_handle_txqueue: descriptor not owned!\n");
1307 abort = TRUE;
1308 break;
1309 }
1310
1311 /* Copy packet data to the buffer */
1312 len = (ptxd->buf_size & GT_TXDESC_BC_MASK) >> GT_TXDESC_BC_SHIFT;
1313
1314 physmem_copy_from_vm(d->vm,pkt_ptr,ptxd->buf_ptr,len);
1315 pkt_ptr += len;
1316 tot_len += len;
1317
1318 /* Clear the OWN bit if this is not the first descriptor */
1319 if (!(ptxd->cmd_stat & GT_TXDESC_F)) {
1320 ptxd->cmd_stat &= ~GT_TXDESC_OWN;
1321 physmem_copy_u32_to_vm(d->vm,tx_current,ptxd->cmd_stat);
1322 }
1323
1324 tx_current = ptxd->next_ptr;
1325
1326 /* Last descriptor or no more desc available ? */
1327 if (ptxd->cmd_stat & GT_TXDESC_L)
1328 break;
1329
1330 if (!tx_current) {
1331 abort = TRUE;
1332 break;
1333 }
1334
1335 /* Fetch the next descriptor */
1336 gt_eth_desc_read(d,tx_current,&ctxd);
1337 ptxd = &ctxd;
1338 }
1339
1340 if ((tot_len != 0) && !abort) {
1341 #if DEBUG_ETH_TX
1342 GT_LOG(d,"Ethernet: sending packet of %u bytes\n",tot_len);
1343 mem_dump(log_file,pkt,tot_len);
1344 #endif
1345 /* send it on wire */
1346 netio_send(port->nio,pkt,tot_len);
1347
1348 /* Update MIB counters */
1349 port->tx_bytes += tot_len;
1350 port->tx_frames++;
1351 }
1352
1353 /* Clear the OWN flag of the first descriptor */
1354 txd0.cmd_stat &= ~GT_TXDESC_OWN;
1355 physmem_copy_u32_to_vm(d->vm,tx_start+4,txd0.cmd_stat);
1356
1357 port->tx_current[queue] = tx_current;
1358
1359 /* Notify host about transmitted packet */
1360 if (queue == 0)
1361 port->icr |= GT_ICR_TXBUFL;
1362 else
1363 port->icr |= GT_ICR_TXBUFH;
1364
1365 done:
1366 if (abort) {
1367 /* TX underrun */
1368 port->icr |= GT_ICR_TXUDR;
1369
1370 if (queue == 0)
1371 port->icr |= GT_ICR_TXERRL;
1372 else
1373 port->icr |= GT_ICR_TXERRH;
1374 } else {
1375 /* End of queue has been reached */
1376 if (!tx_current) {
1377 if (queue == 0)
1378 port->icr |= GT_ICR_TXENDL;
1379 else
1380 port->icr |= GT_ICR_TXENDH;
1381 }
1382 }
1383
1384 /* Update the interrupt status */
1385 gt_eth_update_int_status(d,port);
1386 return(TRUE);
1387 }
1388
1389 /* Handle TX ring of the specified port */
1390 static void gt_eth_handle_port_txqueues(struct gt_data *d,u_int port)
1391 {
1392 gt_eth_handle_txqueue(d,&d->eth_ports[port],0); /* TX Low */
1393 gt_eth_handle_txqueue(d,&d->eth_ports[port],1); /* TX High */
1394 }
1395
1396 /* Handle all TX rings of all Ethernet ports */
1397 static int gt_eth_handle_txqueues(struct gt_data *d)
1398 {
1399 int i;
1400
1401 for(i=0;i<GT_ETH_PORTS;i++)
1402 gt_eth_handle_port_txqueues(d,i);
1403
1404 return(TRUE);
1405 }
1406
1407 /* Inverse a nibble */
1408 static const int inv_nibble[16] = {
1409 0x0, 0x8, 0x4, 0xC, 0x2, 0xA, 0x6, 0xE,
1410 0x1, 0x9, 0x5, 0xD, 0x3, 0xB, 0x7, 0xF
1411 };
1412
1413 /* Inverse a 9-bit value */
1414 static inline u_int gt_hash_inv_9bit(u_int val)
1415 {
1416 u_int res;
1417
1418 res = inv_nibble[val & 0x0F] << 5;
1419 res |= inv_nibble[(val & 0xF0) >> 4] << 1;
1420 res |= (val & 0x100) >> 8;
1421 return(res);
1422 }
1423
1424 /*
1425 * Compute hash value for Ethernet address filtering.
1426 * Two modes are available (p.271 of the GT96100 doc).
1427 */
1428 static u_int gt_eth_hash_value(n_eth_addr_t *addr,int mode)
1429 {
1430 m_uint64_t tmp;
1431 u_int res;
1432 int i;
1433
1434 /* Swap the nibbles */
1435 for(i=0,tmp=0;i<N_ETH_ALEN;i++) {
1436 tmp <<= 8;
1437 tmp |= (inv_nibble[addr->eth_addr_byte[i] & 0x0F]) << 4;
1438 tmp |= inv_nibble[(addr->eth_addr_byte[i] & 0xF0) >> 4];
1439 }
1440
1441 if (mode == 0) {
1442 /* Fill bits 0:8 */
1443 res = (tmp & 0x00000003) | ((tmp & 0x00007f00) >> 6);
1444 res ^= (tmp & 0x00ff8000) >> 15;
1445 res ^= (tmp & 0x1ff000000ULL) >> 24;
1446
1447 /* Fill bits 9:14 */
1448 res |= (tmp & 0xfc) << 7;
1449 } else {
1450 /* Fill bits 0:8 */
1451 res = gt_hash_inv_9bit((tmp & 0x00007fc0) >> 6);
1452 res ^= gt_hash_inv_9bit((tmp & 0x00ff8000) >> 15);
1453 res ^= gt_hash_inv_9bit((tmp & 0x1ff000000ULL) >> 24);
1454
1455 /* Fill bits 9:14 */
1456 res |= (tmp & 0x3f) << 9;
1457 }
1458
1459 return(res);
1460 }
1461
1462 /*
1463 * Walk through the Ethernet hash table.
1464 */
1465 static int gt_eth_hash_lookup(struct gt_data *d,struct eth_port *port,
1466 n_eth_addr_t *addr,m_uint64_t *entry)
1467 {
1468 m_uint64_t eth_val;
1469 m_uint32_t hte_addr;
1470 u_int hash_val;
1471 int i;
1472
1473 eth_val = (m_uint64_t)addr->eth_addr_byte[0] << 3;
1474 eth_val |= (m_uint64_t)addr->eth_addr_byte[1] << 11;
1475 eth_val |= (m_uint64_t)addr->eth_addr_byte[2] << 19;
1476 eth_val |= (m_uint64_t)addr->eth_addr_byte[3] << 27;
1477 eth_val |= (m_uint64_t)addr->eth_addr_byte[4] << 35;
1478 eth_val |= (m_uint64_t)addr->eth_addr_byte[5] << 43;
1479
1480 /* Compute hash value for Ethernet address filtering */
1481 hash_val = gt_eth_hash_value(addr,port->pcr & GT_PCR_HM);
1482
1483 if (port->pcr & GT_PCR_HS) {
1484 /* 1/2K address filtering */
1485 hte_addr = port->ht_addr + ((hash_val & 0x7ff) << 3);
1486 } else {
1487 /* 8K address filtering */
1488 hte_addr = port->ht_addr + (hash_val << 3);
1489 }
1490
1491 #if DEBUG_ETH_HASH
1492 GT_LOG(d,"Hash Lookup for Ethernet address "
1493 "%2.2x:%2.2x:%2.2x:%2.2x:%2.2x:%2.2x: addr=0x%x\n",
1494 addr->eth_addr_byte[0], addr->eth_addr_byte[1],
1495 addr->eth_addr_byte[2], addr->eth_addr_byte[3],
1496 addr->eth_addr_byte[4], addr->eth_addr_byte[5],
1497 hte_addr);
1498 #endif
1499
1500 for(i=0;i<GT_HTE_HOPNUM;i++,hte_addr+=8) {
1501 *entry = ((m_uint64_t)physmem_copy_u32_from_vm(d->vm,hte_addr)) << 32;
1502 *entry |= physmem_copy_u32_from_vm(d->vm,hte_addr+4);
1503
1504 /* Empty entry ? */
1505 if (!(*entry & GT_HTE_VALID))
1506 return(GT_HTLOOKUP_MISS);
1507
1508 /* Skip flag or different Ethernet address: jump to next entry */
1509 if ((*entry & GT_HTE_SKIP) || ((*entry & GT_HTE_ADDR_MASK) != eth_val))
1510 continue;
1511
1512 /* We have the good MAC address in this entry */
1513 return(GT_HTLOOKUP_MATCH);
1514 }
1515
1516 return(GT_HTLOOKUP_HOP_EXCEEDED);
1517 }
1518
1519 /*
1520 * Check if a packet (given its destination address) must be handled
1521 * at RX path.
1522 *
1523 * Return values:
1524 * - 0: Discard packet ;
1525 * - 1: Receive packet ;
1526 * - 2: Receive packet and set "M" bit in RX descriptor.
1527 *
1528 * The documentation is not clear about the M bit in RX descriptor.
1529 * It is described as "Miss" or "Match" depending on the section.
1530 */
1531 static inline int gt_eth_handle_rx_daddr(struct gt_data *d,
1532 struct eth_port *port,
1533 u_int hash_res,
1534 m_uint64_t hash_entry)
1535 {
1536 /* Hop Number exceeded */
1537 if (hash_res == GT_HTLOOKUP_HOP_EXCEEDED)
1538 return(1);
1539
1540 /* Match and hash entry marked as "Receive" */
1541 if ((hash_res == GT_HTLOOKUP_MATCH) && (hash_entry & GT_HTE_RD))
1542 return(2);
1543
1544 /* Miss but hash table default mode to forward ? */
1545 if ((hash_res == GT_HTLOOKUP_MISS) && (port->pcr & GT_PCR_HDM))
1546 return(2);
1547
1548 /* Promiscous Mode */
1549 if (port->pcr & GT_PCR_PM)
1550 return(1);
1551
1552 /* Drop packet for other cases */
1553 return(0);
1554 }
1555
1556 /* Put a packet in buffer of a descriptor */
1557 static void gt_eth_rxdesc_put_pkt(struct gt_data *d,struct eth_desc *rxd,
1558 u_char **pkt,ssize_t *pkt_len)
1559 {
1560 ssize_t len,cp_len;
1561
1562 len = (rxd->buf_size & GT_RXDESC_BS_MASK) >> GT_RXDESC_BS_SHIFT;
1563
1564 /* compute the data length to copy */
1565 cp_len = m_min(len,*pkt_len);
1566
1567 /* copy packet data to the VM physical RAM */
1568 physmem_copy_to_vm(d->vm,*pkt,rxd->buf_ptr,cp_len);
1569
1570 /* set the byte count in descriptor */
1571 rxd->buf_size |= cp_len;
1572
1573 *pkt += cp_len;
1574 *pkt_len -= cp_len;
1575 }
1576
1577 /* Put a packet in the specified RX queue */
1578 static int gt_eth_handle_rxqueue(struct gt_data *d,u_int port_id,u_int queue,
1579 u_char *pkt,ssize_t pkt_len)
1580 {
1581 struct eth_port *port = &d->eth_ports[port_id];
1582 m_uint32_t rx_start,rx_current;
1583 struct eth_desc rxd0,rxdn,*rxdc;
1584 ssize_t tot_len = pkt_len;
1585 u_char *pkt_ptr = pkt;
1586 n_eth_dot1q_hdr_t *hdr;
1587 m_uint64_t hash_entry;
1588 int i,hash_res,addr_action;
1589
1590 /* Truncate the packet if it is too big */
1591 pkt_len = m_min(pkt_len,GT_MAX_PKT_SIZE);
1592
1593 /* Copy the first RX descriptor */
1594 if (!(rx_start = rx_current = port->rx_start[queue]))
1595 goto dma_error;
1596
1597 /* Analyze the Ethernet header */
1598 hdr = (n_eth_dot1q_hdr_t *)pkt;
1599
1600 /* Hash table lookup for address filtering */
1601 hash_res = gt_eth_hash_lookup(d,port,&hdr->daddr,&hash_entry);
1602
1603 #if DEBUG_ETH_HASH
1604 GT_LOG(d,"Hash result: %d, hash_entry=0x%llx\n",hash_res,hash_entry);
1605 #endif
1606
1607 if (!(addr_action = gt_eth_handle_rx_daddr(d,port,hash_res,hash_entry)))
1608 return(FALSE);
1609
1610 /* Load the first RX descriptor */
1611 gt_eth_desc_read(d,rx_start,&rxd0);
1612
1613 #if DEBUG_ETH_RX
1614 GT_LOG(d,"port %u/queue %u: reading desc at 0x%8.8x "
1615 "[buf_size=0x%8.8x,cmd_stat=0x%8.8x,"
1616 "next_ptr=0x%8.8x,buf_ptr=0x%8.8x]\n",
1617 port_id,queue,rx_start,
1618 rxd0.buf_size,rxd0.cmd_stat,rxd0.next_ptr,rxd0.buf_ptr);
1619 #endif
1620
1621 for(i=0,rxdc=&rxd0;tot_len>0;i++)
1622 {
1623 /* We must own the descriptor */
1624 if (!(rxdc->cmd_stat & GT_RXDESC_OWN))
1625 goto dma_error;
1626
1627 /* Put data into the descriptor buffer */
1628 gt_eth_rxdesc_put_pkt(d,rxdc,&pkt_ptr,&tot_len);
1629
1630 /* Clear the OWN bit */
1631 rxdc->cmd_stat &= ~GT_RXDESC_OWN;
1632
1633 /* We have finished if the complete packet has been stored */
1634 if (tot_len == 0) {
1635 rxdc->cmd_stat |= GT_RXDESC_L;
1636 rxdc->buf_size += 4; /* Add 4 bytes for CRC */
1637 }
1638
1639 /* Update the descriptor in host memory (but not the 1st) */
1640 if (i != 0)
1641 gt_eth_desc_write(d,rx_current,rxdc);
1642
1643 /* Get address of the next descriptor */
1644 rx_current = rxdc->next_ptr;
1645
1646 if (tot_len == 0)
1647 break;
1648
1649 if (!rx_current)
1650 goto dma_error;
1651
1652 /* Read the next descriptor from VM physical RAM */
1653 gt_eth_desc_read(d,rx_current,&rxdn);
1654 rxdc = &rxdn;
1655 }
1656
1657 /* Update the RX pointers */
1658 port->rx_start[queue] = port->rx_current[queue] = rx_current;
1659
1660 /* Update the first RX descriptor */
1661 rxd0.cmd_stat |= GT_RXDESC_F;
1662
1663 if (hash_res == GT_HTLOOKUP_HOP_EXCEEDED)
1664 rxd0.cmd_stat |= GT_RXDESC_HE;
1665
1666 if (addr_action == 2)
1667 rxd0.cmd_stat |= GT_RXDESC_M;
1668
1669 if (ntohs(hdr->type) <= N_ETH_MTU) /* 802.3 frame */
1670 rxd0.cmd_stat |= GT_RXDESC_FT;
1671
1672 gt_eth_desc_write(d,rx_start,&rxd0);
1673
1674 /* Update MIB counters */
1675 port->rx_bytes += pkt_len;
1676 port->rx_frames++;
1677
1678 /* Indicate that we have a frame ready */
1679 port->icr |= (GT_ICR_RXBUFQ0 << queue) | GT_ICR_RXBUF;
1680 gt_eth_update_int_status(d,port);
1681 return(TRUE);
1682
1683 dma_error:
1684 port->icr |= (GT_ICR_RXERRQ0 << queue) | GT_ICR_RXERR;
1685 gt_eth_update_int_status(d,port);
1686 return(FALSE);
1687 }
1688
1689 /* Handle RX packet for an Ethernet port */
1690 static int gt_eth_handle_rx_pkt(netio_desc_t *nio,
1691 u_char *pkt,ssize_t pkt_len,
1692 struct gt_data *d,void *arg)
1693 {
1694 u_int queue,port_id = (int)arg;
1695 struct eth_port *port;
1696
1697 port = &d->eth_ports[port_id];
1698
1699 /* Check if RX DMA is active */
1700 if (!(port->sdcmr & GT_SDCMR_ERD))
1701 return(FALSE);
1702
1703 queue = 0; /* At this time, only put packet in queue 0 */
1704 gt_eth_handle_rxqueue(d,port_id,queue,pkt,pkt_len);
1705 return(TRUE);
1706 }
1707
1708 /* Shutdown a GT system controller */
1709 void dev_gt_shutdown(vm_instance_t *vm,struct gt_data *d)
1710 {
1711 if (d != NULL) {
1712 /* Stop the TX ring scanner */
1713 ptask_remove(d->eth_tx_tid);
1714
1715 /* Remove the device */
1716 dev_remove(vm,&d->dev);
1717
1718 /* Remove the PCI device */
1719 pci_dev_remove(d->pci_dev);
1720
1721 /* Free the structure itself */
1722 free(d);
1723 }
1724 }
1725
1726 /* Create a new GT64010 controller */
1727 int dev_gt64010_init(vm_instance_t *vm,char *name,
1728 m_uint64_t paddr,m_uint32_t len,u_int irq)
1729 {
1730 struct gt_data *d;
1731
1732 if (!(d = malloc(sizeof(*d)))) {
1733 fprintf(stderr,"gt64010: unable to create device data.\n");
1734 return(-1);
1735 }
1736
1737 memset(d,0,sizeof(*d));
1738 d->vm = vm;
1739 d->bus[0] = vm->pci_bus[0];
1740
1741 vm_object_init(&d->vm_obj);
1742 d->vm_obj.name = name;
1743 d->vm_obj.data = d;
1744 d->vm_obj.shutdown = (vm_shutdown_t)dev_gt_shutdown;
1745
1746 dev_init(&d->dev);
1747 d->dev.name = name;
1748 d->dev.priv_data = d;
1749 d->dev.phys_addr = paddr;
1750 d->dev.phys_len = len;
1751 d->dev.handler = dev_gt64010_access;
1752
1753 /* Add the controller as a PCI device */
1754 if (!pci_dev_lookup(d->bus[0],0,0,0)) {
1755 d->pci_dev = pci_dev_add(d->bus[0],name,
1756 PCI_VENDOR_GALILEO,PCI_PRODUCT_GALILEO_GT64010,
1757 0,0,irq,d,NULL,NULL,NULL);
1758
1759 if (!d->pci_dev) {
1760 fprintf(stderr,"gt64010: unable to create PCI device.\n");
1761 return(-1);
1762 }
1763 }
1764
1765 /* Map this device to the VM */
1766 vm_bind_device(vm,&d->dev);
1767 vm_object_add(vm,&d->vm_obj);
1768 return(0);
1769 }
1770
1771 /*
1772 * pci_gt64120_read()
1773 *
1774 * Read a PCI register.
1775 */
1776 static m_uint32_t pci_gt64120_read(cpu_gen_t *cpu,struct pci_device *dev,
1777 int reg)
1778 {
1779 switch (reg) {
1780 case 0x08:
1781 return(0x03008005);
1782 default:
1783 return(0);
1784 }
1785 }
1786
1787 /* Create a new GT64120 controller */
1788 int dev_gt64120_init(vm_instance_t *vm,char *name,
1789 m_uint64_t paddr,m_uint32_t len,u_int irq)
1790 {
1791 struct gt_data *d;
1792
1793 if (!(d = malloc(sizeof(*d)))) {
1794 fprintf(stderr,"gt64120: unable to create device data.\n");
1795 return(-1);
1796 }
1797
1798 memset(d,0,sizeof(*d));
1799 d->vm = vm;
1800 d->bus[0] = vm->pci_bus[0];
1801 d->bus[1] = vm->pci_bus[1];
1802
1803 vm_object_init(&d->vm_obj);
1804 d->vm_obj.name = name;
1805 d->vm_obj.data = d;
1806 d->vm_obj.shutdown = (vm_shutdown_t)dev_gt_shutdown;
1807
1808 dev_init(&d->dev);
1809 d->dev.name = name;
1810 d->dev.priv_data = d;
1811 d->dev.phys_addr = paddr;
1812 d->dev.phys_len = len;
1813 d->dev.handler = dev_gt64120_access;
1814
1815 /* Add the controller as a PCI device */
1816 if (!pci_dev_lookup(d->bus[0],0,0,0)) {
1817 d->pci_dev = pci_dev_add(d->bus[0],name,
1818 PCI_VENDOR_GALILEO,PCI_PRODUCT_GALILEO_GT64120,
1819 0,0,irq,d,NULL,pci_gt64120_read,NULL);
1820 if (!d->pci_dev) {
1821 fprintf(stderr,"gt64120: unable to create PCI device.\n");
1822 return(-1);
1823 }
1824 }
1825
1826 /* Map this device to the VM */
1827 vm_bind_device(vm,&d->dev);
1828 vm_object_add(vm,&d->vm_obj);
1829 return(0);
1830 }
1831
1832 /*
1833 * pci_gt96100_read()
1834 *
1835 * Read a PCI register.
1836 */
1837 static m_uint32_t pci_gt96100_read(cpu_gen_t *cpu,struct pci_device *dev,
1838 int reg)
1839 {
1840 switch (reg) {
1841 case 0x08:
1842 return(0x03008005);
1843 default:
1844 return(0);
1845 }
1846 }
1847
1848 /* Create a new GT96100 controller */
1849 int dev_gt96100_init(vm_instance_t *vm,char *name,
1850 m_uint64_t paddr,m_uint32_t len,
1851 u_int dma_irq,u_int eth_irq)
1852 {
1853 struct gt_data *d;
1854
1855 if (!(d = malloc(sizeof(*d)))) {
1856 fprintf(stderr,"gt96100: unable to create device data.\n");
1857 return(-1);
1858 }
1859
1860 memset(d,0,sizeof(*d));
1861 d->name = name;
1862 d->vm = vm;
1863 d->eth_irq = eth_irq;
1864 d->bus[0] = vm->pci_bus[0];
1865 d->bus[1] = vm->pci_bus[1];
1866
1867 vm_object_init(&d->vm_obj);
1868 d->vm_obj.name = name;
1869 d->vm_obj.data = d;
1870 d->vm_obj.shutdown = (vm_shutdown_t)dev_gt_shutdown;
1871
1872 dev_init(&d->dev);
1873 d->dev.name = name;
1874 d->dev.priv_data = d;
1875 d->dev.phys_addr = paddr;
1876 d->dev.phys_len = len;
1877 d->dev.handler = dev_gt96100_access;
1878
1879 /* Add the controller as a PCI device */
1880 if (!pci_dev_lookup(d->bus[0],0,0,0)) {
1881 d->pci_dev = pci_dev_add(d->bus[0],name,
1882 PCI_VENDOR_GALILEO,PCI_PRODUCT_GALILEO_GT96100,
1883 0,0,dma_irq,d,NULL,pci_gt96100_read,NULL);
1884 if (!d->pci_dev) {
1885 fprintf(stderr,"gt96100: unable to create PCI device.\n");
1886 return(-1);
1887 }
1888 }
1889
1890 /* Start the TX ring scanner */
1891 d->eth_tx_tid = ptask_add((ptask_callback)gt_eth_handle_txqueues,d,NULL);
1892
1893 /* Map this device to the VM */
1894 vm_bind_device(vm,&d->dev);
1895 vm_object_add(vm,&d->vm_obj);
1896 return(0);
1897 }
1898
1899 /* Bind a NIO to GT96100 device */
1900 int dev_gt96100_set_nio(struct gt_data *d,u_int port_id,netio_desc_t *nio)
1901 {
1902 struct eth_port *port;
1903
1904 if (port_id >= GT_ETH_PORTS)
1905 return(-1);
1906
1907 port = &d->eth_ports[port_id];
1908
1909 /* check that a NIO is not already bound */
1910 if (port->nio != NULL)
1911 return(-1);
1912
1913 port->nio = nio;
1914 netio_rxl_add(nio,(netio_rx_handler_t)gt_eth_handle_rx_pkt,
1915 d,(void *)port_id);
1916 return(0);
1917 }
1918
1919 /* Unbind a NIO from a GT96100 device */
1920 int dev_gt96100_unset_nio(struct gt_data *d,u_int port_id)
1921 {
1922 struct eth_port *port;
1923
1924 if (port_id >= GT_ETH_PORTS)
1925 return(-1);
1926
1927 port = &d->eth_ports[port_id];
1928
1929 if (port->nio != NULL) {
1930 netio_rxl_remove(port->nio);
1931 port->nio = NULL;
1932 }
1933
1934 return(0);
1935 }

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