1 // SPDX-License-Identifier: GPL-2.0-only
2 /*
3 * Copyright 2016 Broadcom
4 */
5
6 /*
7 * Broadcom PDC Mailbox Driver
8 * The PDC provides a ring based programming interface to one or more hardware
9 * offload engines. For example, the PDC driver works with both SPU-M and SPU2
10 * cryptographic offload hardware. In some chips the PDC is referred to as MDE,
11 * and in others the FA2/FA+ hardware is used with this PDC driver.
12 *
13 * The PDC driver registers with the Linux mailbox framework as a mailbox
14 * controller, once for each PDC instance. Ring 0 for each PDC is registered as
15 * a mailbox channel. The PDC driver uses interrupts to determine when data
16 * transfers to and from an offload engine are complete. The PDC driver uses
17 * threaded IRQs so that response messages are handled outside of interrupt
18 * context.
19 *
20 * The PDC driver allows multiple messages to be pending in the descriptor
21 * rings. The tx_msg_start descriptor index indicates where the last message
22 * starts. The txin_numd value at this index indicates how many descriptor
23 * indexes make up the message. Similar state is kept on the receive side. When
24 * an rx interrupt indicates a response is ready, the PDC driver processes numd
25 * descriptors from the tx and rx ring, thus processing one response at a time.
26 */
27
28 #include <linux/errno.h>
29 #include <linux/module.h>
30 #include <linux/init.h>
31 #include <linux/slab.h>
32 #include <linux/debugfs.h>
33 #include <linux/interrupt.h>
34 #include <linux/wait.h>
35 #include <linux/platform_device.h>
36 #include <linux/io.h>
37 #include <linux/of.h>
38 #include <linux/of_device.h>
39 #include <linux/of_address.h>
40 #include <linux/of_irq.h>
41 #include <linux/mailbox_controller.h>
42 #include <linux/mailbox/brcm-message.h>
43 #include <linux/scatterlist.h>
44 #include <linux/dma-direction.h>
45 #include <linux/dma-mapping.h>
46 #include <linux/dmapool.h>
47
48 #define PDC_SUCCESS 0
49
50 #define RING_ENTRY_SIZE sizeof(struct dma64dd)
51
52 /* # entries in PDC dma ring */
53 #define PDC_RING_ENTRIES 512
54 /*
55 * Minimum number of ring descriptor entries that must be free to tell mailbox
56 * framework that it can submit another request
57 */
58 #define PDC_RING_SPACE_MIN 15
59
60 #define PDC_RING_SIZE (PDC_RING_ENTRIES * RING_ENTRY_SIZE)
61 /* Rings are 8k aligned */
62 #define RING_ALIGN_ORDER 13
63 #define RING_ALIGN BIT(RING_ALIGN_ORDER)
64
65 #define RX_BUF_ALIGN_ORDER 5
66 #define RX_BUF_ALIGN BIT(RX_BUF_ALIGN_ORDER)
67
68 /* descriptor bumping macros */
69 #define XXD(x, max_mask) ((x) & (max_mask))
70 #define TXD(x, max_mask) XXD((x), (max_mask))
71 #define RXD(x, max_mask) XXD((x), (max_mask))
72 #define NEXTTXD(i, max_mask) TXD((i) + 1, (max_mask))
73 #define PREVTXD(i, max_mask) TXD((i) - 1, (max_mask))
74 #define NEXTRXD(i, max_mask) RXD((i) + 1, (max_mask))
75 #define PREVRXD(i, max_mask) RXD((i) - 1, (max_mask))
76 #define NTXDACTIVE(h, t, max_mask) TXD((t) - (h), (max_mask))
77 #define NRXDACTIVE(h, t, max_mask) RXD((t) - (h), (max_mask))
78
79 /* Length of BCM header at start of SPU msg, in bytes */
80 #define BCM_HDR_LEN 8
81
82 /*
83 * PDC driver reserves ringset 0 on each SPU for its own use. The driver does
84 * not currently support use of multiple ringsets on a single PDC engine.
85 */
86 #define PDC_RINGSET 0
87
88 /*
89 * Interrupt mask and status definitions. Enable interrupts for tx and rx on
90 * ring 0
91 */
92 #define PDC_RCVINT_0 (16 + PDC_RINGSET)
93 #define PDC_RCVINTEN_0 BIT(PDC_RCVINT_0)
94 #define PDC_INTMASK (PDC_RCVINTEN_0)
95 #define PDC_LAZY_FRAMECOUNT 1
96 #define PDC_LAZY_TIMEOUT 10000
97 #define PDC_LAZY_INT (PDC_LAZY_TIMEOUT | (PDC_LAZY_FRAMECOUNT << 24))
98 #define PDC_INTMASK_OFFSET 0x24
99 #define PDC_INTSTATUS_OFFSET 0x20
100 #define PDC_RCVLAZY0_OFFSET (0x30 + 4 * PDC_RINGSET)
101 #define FA_RCVLAZY0_OFFSET 0x100
102
103 /*
104 * For SPU2, configure MDE_CKSUM_CONTROL to write 17 bytes of metadata
105 * before frame
106 */
107 #define PDC_SPU2_RESP_HDR_LEN 17
108 #define PDC_CKSUM_CTRL BIT(27)
109 #define PDC_CKSUM_CTRL_OFFSET 0x400
110
111 #define PDC_SPUM_RESP_HDR_LEN 32
112
113 /*
114 * Sets the following bits for write to transmit control reg:
115 * 11 - PtyChkDisable - parity check is disabled
116 * 20:18 - BurstLen = 3 -> 2^7 = 128 byte data reads from memory
117 */
118 #define PDC_TX_CTL 0x000C0800
119
120 /* Bit in tx control reg to enable tx channel */
121 #define PDC_TX_ENABLE 0x1
122
123 /*
124 * Sets the following bits for write to receive control reg:
125 * 7:1 - RcvOffset - size in bytes of status region at start of rx frame buf
126 * 9 - SepRxHdrDescEn - place start of new frames only in descriptors
127 * that have StartOfFrame set
128 * 10 - OflowContinue - on rx FIFO overflow, clear rx fifo, discard all
129 * remaining bytes in current frame, report error
130 * in rx frame status for current frame
131 * 11 - PtyChkDisable - parity check is disabled
132 * 20:18 - BurstLen = 3 -> 2^7 = 128 byte data reads from memory
133 */
134 #define PDC_RX_CTL 0x000C0E00
135
136 /* Bit in rx control reg to enable rx channel */
137 #define PDC_RX_ENABLE 0x1
138
139 #define CRYPTO_D64_RS0_CD_MASK ((PDC_RING_ENTRIES * RING_ENTRY_SIZE) - 1)
140
141 /* descriptor flags */
142 #define D64_CTRL1_EOT BIT(28) /* end of descriptor table */
143 #define D64_CTRL1_IOC BIT(29) /* interrupt on complete */
144 #define D64_CTRL1_EOF BIT(30) /* end of frame */
145 #define D64_CTRL1_SOF BIT(31) /* start of frame */
146
147 #define RX_STATUS_OVERFLOW 0x00800000
148 #define RX_STATUS_LEN 0x0000FFFF
149
150 #define PDC_TXREGS_OFFSET 0x200
151 #define PDC_RXREGS_OFFSET 0x220
152
153 /* Maximum size buffer the DMA engine can handle */
154 #define PDC_DMA_BUF_MAX 16384
155
156 enum pdc_hw {
157 FA_HW, /* FA2/FA+ hardware (i.e. Northstar Plus) */
158 PDC_HW /* PDC/MDE hardware (i.e. Northstar 2, Pegasus) */
159 };
160
161 struct pdc_dma_map {
162 void *ctx; /* opaque context associated with frame */
163 };
164
165 /* dma descriptor */
166 struct dma64dd {
167 u32 ctrl1; /* misc control bits */
168 u32 ctrl2; /* buffer count and address extension */
169 u32 addrlow; /* memory address of the date buffer, bits 31:0 */
170 u32 addrhigh; /* memory address of the date buffer, bits 63:32 */
171 };
172
173 /* dma registers per channel(xmt or rcv) */
174 struct dma64_regs {
175 u32 control; /* enable, et al */
176 u32 ptr; /* last descriptor posted to chip */
177 u32 addrlow; /* descriptor ring base address low 32-bits */
178 u32 addrhigh; /* descriptor ring base address bits 63:32 */
179 u32 status0; /* last rx descriptor written by hw */
180 u32 status1; /* driver does not use */
181 };
182
183 /* cpp contortions to concatenate w/arg prescan */
184 #ifndef PAD
185 #define _PADLINE(line) pad ## line
186 #define _XSTR(line) _PADLINE(line)
187 #define PAD _XSTR(__LINE__)
188 #endif /* PAD */
189
190 /* dma registers. matches hw layout. */
191 struct dma64 {
192 struct dma64_regs dmaxmt; /* dma tx */
193 u32 PAD[2];
194 struct dma64_regs dmarcv; /* dma rx */
195 u32 PAD[2];
196 };
197
198 /* PDC registers */
199 struct pdc_regs {
200 u32 devcontrol; /* 0x000 */
201 u32 devstatus; /* 0x004 */
202 u32 PAD;
203 u32 biststatus; /* 0x00c */
204 u32 PAD[4];
205 u32 intstatus; /* 0x020 */
206 u32 intmask; /* 0x024 */
207 u32 gptimer; /* 0x028 */
208
209 u32 PAD;
210 u32 intrcvlazy_0; /* 0x030 (Only in PDC, not FA2) */
211 u32 intrcvlazy_1; /* 0x034 (Only in PDC, not FA2) */
212 u32 intrcvlazy_2; /* 0x038 (Only in PDC, not FA2) */
213 u32 intrcvlazy_3; /* 0x03c (Only in PDC, not FA2) */
214
215 u32 PAD[48];
216 u32 fa_intrecvlazy; /* 0x100 (Only in FA2, not PDC) */
217 u32 flowctlthresh; /* 0x104 */
218 u32 wrrthresh; /* 0x108 */
219 u32 gmac_idle_cnt_thresh; /* 0x10c */
220
221 u32 PAD[4];
222 u32 ifioaccessaddr; /* 0x120 */
223 u32 ifioaccessbyte; /* 0x124 */
224 u32 ifioaccessdata; /* 0x128 */
225
226 u32 PAD[21];
227 u32 phyaccess; /* 0x180 */
228 u32 PAD;
229 u32 phycontrol; /* 0x188 */
230 u32 txqctl; /* 0x18c */
231 u32 rxqctl; /* 0x190 */
232 u32 gpioselect; /* 0x194 */
233 u32 gpio_output_en; /* 0x198 */
234 u32 PAD; /* 0x19c */
235 u32 txq_rxq_mem_ctl; /* 0x1a0 */
236 u32 memory_ecc_status; /* 0x1a4 */
237 u32 serdes_ctl; /* 0x1a8 */
238 u32 serdes_status0; /* 0x1ac */
239 u32 serdes_status1; /* 0x1b0 */
240 u32 PAD[11]; /* 0x1b4-1dc */
241 u32 clk_ctl_st; /* 0x1e0 */
242 u32 hw_war; /* 0x1e4 (Only in PDC, not FA2) */
243 u32 pwrctl; /* 0x1e8 */
244 u32 PAD[5];
245
246 #define PDC_NUM_DMA_RINGS 4
247 struct dma64 dmaregs[PDC_NUM_DMA_RINGS]; /* 0x0200 - 0x2fc */
248
249 /* more registers follow, but we don't use them */
250 };
251
252 /* structure for allocating/freeing DMA rings */
253 struct pdc_ring_alloc {
254 dma_addr_t dmabase; /* DMA address of start of ring */
255 void *vbase; /* base kernel virtual address of ring */
256 u32 size; /* ring allocation size in bytes */
257 };
258
259 /*
260 * context associated with a receive descriptor.
261 * @rxp_ctx: opaque context associated with frame that starts at each
262 * rx ring index.
263 * @dst_sg: Scatterlist used to form reply frames beginning at a given ring
264 * index. Retained in order to unmap each sg after reply is processed.
265 * @rxin_numd: Number of rx descriptors associated with the message that starts
266 * at a descriptor index. Not set for every index. For example,
267 * if descriptor index i points to a scatterlist with 4 entries,
268 * then the next three descriptor indexes don't have a value set.
269 * @resp_hdr: Virtual address of buffer used to catch DMA rx status
270 * @resp_hdr_daddr: physical address of DMA rx status buffer
271 */
272 struct pdc_rx_ctx {
273 void *rxp_ctx;
274 struct scatterlist *dst_sg;
275 u32 rxin_numd;
276 void *resp_hdr;
277 dma_addr_t resp_hdr_daddr;
278 };
279
280 /* PDC state structure */
281 struct pdc_state {
282 /* Index of the PDC whose state is in this structure instance */
283 u8 pdc_idx;
284
285 /* Platform device for this PDC instance */
286 struct platform_device *pdev;
287
288 /*
289 * Each PDC instance has a mailbox controller. PDC receives request
290 * messages through mailboxes, and sends response messages through the
291 * mailbox framework.
292 */
293 struct mbox_controller mbc;
294
295 unsigned int pdc_irq;
296
297 /* tasklet for deferred processing after DMA rx interrupt */
298 struct tasklet_struct rx_tasklet;
299
300 /* Number of bytes of receive status prior to each rx frame */
301 u32 rx_status_len;
302 /* Whether a BCM header is prepended to each frame */
303 bool use_bcm_hdr;
304 /* Sum of length of BCM header and rx status header */
305 u32 pdc_resp_hdr_len;
306
307 /* The base virtual address of DMA hw registers */
308 void __iomem *pdc_reg_vbase;
309
310 /* Pool for allocation of DMA rings */
311 struct dma_pool *ring_pool;
312
313 /* Pool for allocation of metadata buffers for response messages */
314 struct dma_pool *rx_buf_pool;
315
316 /*
317 * The base virtual address of DMA tx/rx descriptor rings. Corresponding
318 * DMA address and size of ring allocation.
319 */
320 struct pdc_ring_alloc tx_ring_alloc;
321 struct pdc_ring_alloc rx_ring_alloc;
322
323 struct pdc_regs *regs; /* start of PDC registers */
324
325 struct dma64_regs *txregs_64; /* dma tx engine registers */
326 struct dma64_regs *rxregs_64; /* dma rx engine registers */
327
328 /*
329 * Arrays of PDC_RING_ENTRIES descriptors
330 * To use multiple ringsets, this needs to be extended
331 */
332 struct dma64dd *txd_64; /* tx descriptor ring */
333 struct dma64dd *rxd_64; /* rx descriptor ring */
334
335 /* descriptor ring sizes */
336 u32 ntxd; /* # tx descriptors */
337 u32 nrxd; /* # rx descriptors */
338 u32 nrxpost; /* # rx buffers to keep posted */
339 u32 ntxpost; /* max number of tx buffers that can be posted */
340
341 /*
342 * Index of next tx descriptor to reclaim. That is, the descriptor
343 * index of the oldest tx buffer for which the host has yet to process
344 * the corresponding response.
345 */
346 u32 txin;
347
348 /*
349 * Index of the first receive descriptor for the sequence of
350 * message fragments currently under construction. Used to build up
351 * the rxin_numd count for a message. Updated to rxout when the host
352 * starts a new sequence of rx buffers for a new message.
353 */
354 u32 tx_msg_start;
355
356 /* Index of next tx descriptor to post. */
357 u32 txout;
358
359 /*
360 * Number of tx descriptors associated with the message that starts
361 * at this tx descriptor index.
362 */
363 u32 txin_numd[PDC_RING_ENTRIES];
364
365 /*
366 * Index of next rx descriptor to reclaim. This is the index of
367 * the next descriptor whose data has yet to be processed by the host.
368 */
369 u32 rxin;
370
371 /*
372 * Index of the first receive descriptor for the sequence of
373 * message fragments currently under construction. Used to build up
374 * the rxin_numd count for a message. Updated to rxout when the host
375 * starts a new sequence of rx buffers for a new message.
376 */
377 u32 rx_msg_start;
378
379 /*
380 * Saved value of current hardware rx descriptor index.
381 * The last rx buffer written by the hw is the index previous to
382 * this one.
383 */
384 u32 last_rx_curr;
385
386 /* Index of next rx descriptor to post. */
387 u32 rxout;
388
389 struct pdc_rx_ctx rx_ctx[PDC_RING_ENTRIES];
390
391 /*
392 * Scatterlists used to form request and reply frames beginning at a
393 * given ring index. Retained in order to unmap each sg after reply
394 * is processed
395 */
396 struct scatterlist *src_sg[PDC_RING_ENTRIES];
397
398 /* counters */
399 u32 pdc_requests; /* number of request messages submitted */
400 u32 pdc_replies; /* number of reply messages received */
401 u32 last_tx_not_done; /* too few tx descriptors to indicate done */
402 u32 tx_ring_full; /* unable to accept msg because tx ring full */
403 u32 rx_ring_full; /* unable to accept msg because rx ring full */
404 u32 txnobuf; /* unable to create tx descriptor */
405 u32 rxnobuf; /* unable to create rx descriptor */
406 u32 rx_oflow; /* count of rx overflows */
407
408 /* hardware type - FA2 or PDC/MDE */
409 enum pdc_hw hw_type;
410 };
411
412 /* Global variables */
413
414 struct pdc_globals {
415 /* Actual number of SPUs in hardware, as reported by device tree */
416 u32 num_spu;
417 };
418
419 static struct pdc_globals pdcg;
420
421 /* top level debug FS directory for PDC driver */
422 static struct dentry *debugfs_dir;
423
pdc_debugfs_read(struct file * filp,char __user * ubuf,size_t count,loff_t * offp)424 static ssize_t pdc_debugfs_read(struct file *filp, char __user *ubuf,
425 size_t count, loff_t *offp)
426 {
427 struct pdc_state *pdcs;
428 char *buf;
429 ssize_t ret, out_offset, out_count;
430
431 out_count = 512;
432
433 buf = kmalloc(out_count, GFP_KERNEL);
434 if (!buf)
435 return -ENOMEM;
436
437 pdcs = filp->private_data;
438 out_offset = 0;
439 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
440 "SPU %u stats:\n", pdcs->pdc_idx);
441 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
442 "PDC requests....................%u\n",
443 pdcs->pdc_requests);
444 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
445 "PDC responses...................%u\n",
446 pdcs->pdc_replies);
447 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
448 "Tx not done.....................%u\n",
449 pdcs->last_tx_not_done);
450 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
451 "Tx ring full....................%u\n",
452 pdcs->tx_ring_full);
453 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
454 "Rx ring full....................%u\n",
455 pdcs->rx_ring_full);
456 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
457 "Tx desc write fail. Ring full...%u\n",
458 pdcs->txnobuf);
459 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
460 "Rx desc write fail. Ring full...%u\n",
461 pdcs->rxnobuf);
462 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
463 "Receive overflow................%u\n",
464 pdcs->rx_oflow);
465 out_offset += scnprintf(buf + out_offset, out_count - out_offset,
466 "Num frags in rx ring............%u\n",
467 NRXDACTIVE(pdcs->rxin, pdcs->last_rx_curr,
468 pdcs->nrxpost));
469
470 if (out_offset > out_count)
471 out_offset = out_count;
472
473 ret = simple_read_from_buffer(ubuf, count, offp, buf, out_offset);
474 kfree(buf);
475 return ret;
476 }
477
478 static const struct file_operations pdc_debugfs_stats = {
479 .owner = THIS_MODULE,
480 .open = simple_open,
481 .read = pdc_debugfs_read,
482 };
483
484 /**
485 * pdc_setup_debugfs() - Create the debug FS directories. If the top-level
486 * directory has not yet been created, create it now. Create a stats file in
487 * this directory for a SPU.
488 * @pdcs: PDC state structure
489 */
pdc_setup_debugfs(struct pdc_state * pdcs)490 static void pdc_setup_debugfs(struct pdc_state *pdcs)
491 {
492 char spu_stats_name[16];
493
494 if (!debugfs_initialized())
495 return;
496
497 snprintf(spu_stats_name, 16, "pdc%d_stats", pdcs->pdc_idx);
498 if (!debugfs_dir)
499 debugfs_dir = debugfs_create_dir(KBUILD_MODNAME, NULL);
500
501 /* S_IRUSR == 0400 */
502 debugfs_create_file(spu_stats_name, 0400, debugfs_dir, pdcs,
503 &pdc_debugfs_stats);
504 }
505
pdc_free_debugfs(void)506 static void pdc_free_debugfs(void)
507 {
508 debugfs_remove_recursive(debugfs_dir);
509 debugfs_dir = NULL;
510 }
511
512 /**
513 * pdc_build_rxd() - Build DMA descriptor to receive SPU result.
514 * @pdcs: PDC state for SPU that will generate result
515 * @dma_addr: DMA address of buffer that descriptor is being built for
516 * @buf_len: Length of the receive buffer, in bytes
517 * @flags: Flags to be stored in descriptor
518 */
519 static inline void
pdc_build_rxd(struct pdc_state * pdcs,dma_addr_t dma_addr,u32 buf_len,u32 flags)520 pdc_build_rxd(struct pdc_state *pdcs, dma_addr_t dma_addr,
521 u32 buf_len, u32 flags)
522 {
523 struct device *dev = &pdcs->pdev->dev;
524 struct dma64dd *rxd = &pdcs->rxd_64[pdcs->rxout];
525
526 dev_dbg(dev,
527 "Writing rx descriptor for PDC %u at index %u with length %u. flags %#x\n",
528 pdcs->pdc_idx, pdcs->rxout, buf_len, flags);
529
530 rxd->addrlow = cpu_to_le32(lower_32_bits(dma_addr));
531 rxd->addrhigh = cpu_to_le32(upper_32_bits(dma_addr));
532 rxd->ctrl1 = cpu_to_le32(flags);
533 rxd->ctrl2 = cpu_to_le32(buf_len);
534
535 /* bump ring index and return */
536 pdcs->rxout = NEXTRXD(pdcs->rxout, pdcs->nrxpost);
537 }
538
539 /**
540 * pdc_build_txd() - Build a DMA descriptor to transmit a SPU request to
541 * hardware.
542 * @pdcs: PDC state for the SPU that will process this request
543 * @dma_addr: DMA address of packet to be transmitted
544 * @buf_len: Length of tx buffer, in bytes
545 * @flags: Flags to be stored in descriptor
546 */
547 static inline void
pdc_build_txd(struct pdc_state * pdcs,dma_addr_t dma_addr,u32 buf_len,u32 flags)548 pdc_build_txd(struct pdc_state *pdcs, dma_addr_t dma_addr, u32 buf_len,
549 u32 flags)
550 {
551 struct device *dev = &pdcs->pdev->dev;
552 struct dma64dd *txd = &pdcs->txd_64[pdcs->txout];
553
554 dev_dbg(dev,
555 "Writing tx descriptor for PDC %u at index %u with length %u, flags %#x\n",
556 pdcs->pdc_idx, pdcs->txout, buf_len, flags);
557
558 txd->addrlow = cpu_to_le32(lower_32_bits(dma_addr));
559 txd->addrhigh = cpu_to_le32(upper_32_bits(dma_addr));
560 txd->ctrl1 = cpu_to_le32(flags);
561 txd->ctrl2 = cpu_to_le32(buf_len);
562
563 /* bump ring index and return */
564 pdcs->txout = NEXTTXD(pdcs->txout, pdcs->ntxpost);
565 }
566
567 /**
568 * pdc_receive_one() - Receive a response message from a given SPU.
569 * @pdcs: PDC state for the SPU to receive from
570 *
571 * When the return code indicates success, the response message is available in
572 * the receive buffers provided prior to submission of the request.
573 *
574 * Return: PDC_SUCCESS if one or more receive descriptors was processed
575 * -EAGAIN indicates that no response message is available
576 * -EIO an error occurred
577 */
578 static int
pdc_receive_one(struct pdc_state * pdcs)579 pdc_receive_one(struct pdc_state *pdcs)
580 {
581 struct device *dev = &pdcs->pdev->dev;
582 struct mbox_controller *mbc;
583 struct mbox_chan *chan;
584 struct brcm_message mssg;
585 u32 len, rx_status;
586 u32 num_frags;
587 u8 *resp_hdr; /* virtual addr of start of resp message DMA header */
588 u32 frags_rdy; /* number of fragments ready to read */
589 u32 rx_idx; /* ring index of start of receive frame */
590 dma_addr_t resp_hdr_daddr;
591 struct pdc_rx_ctx *rx_ctx;
592
593 mbc = &pdcs->mbc;
594 chan = &mbc->chans[0];
595 mssg.type = BRCM_MESSAGE_SPU;
596
597 /*
598 * return if a complete response message is not yet ready.
599 * rxin_numd[rxin] is the number of fragments in the next msg
600 * to read.
601 */
602 frags_rdy = NRXDACTIVE(pdcs->rxin, pdcs->last_rx_curr, pdcs->nrxpost);
603 if ((frags_rdy == 0) ||
604 (frags_rdy < pdcs->rx_ctx[pdcs->rxin].rxin_numd))
605 /* No response ready */
606 return -EAGAIN;
607
608 num_frags = pdcs->txin_numd[pdcs->txin];
609 WARN_ON(num_frags == 0);
610
611 dma_unmap_sg(dev, pdcs->src_sg[pdcs->txin],
612 sg_nents(pdcs->src_sg[pdcs->txin]), DMA_TO_DEVICE);
613
614 pdcs->txin = (pdcs->txin + num_frags) & pdcs->ntxpost;
615
616 dev_dbg(dev, "PDC %u reclaimed %d tx descriptors",
617 pdcs->pdc_idx, num_frags);
618
619 rx_idx = pdcs->rxin;
620 rx_ctx = &pdcs->rx_ctx[rx_idx];
621 num_frags = rx_ctx->rxin_numd;
622 /* Return opaque context with result */
623 mssg.ctx = rx_ctx->rxp_ctx;
624 rx_ctx->rxp_ctx = NULL;
625 resp_hdr = rx_ctx->resp_hdr;
626 resp_hdr_daddr = rx_ctx->resp_hdr_daddr;
627 dma_unmap_sg(dev, rx_ctx->dst_sg, sg_nents(rx_ctx->dst_sg),
628 DMA_FROM_DEVICE);
629
630 pdcs->rxin = (pdcs->rxin + num_frags) & pdcs->nrxpost;
631
632 dev_dbg(dev, "PDC %u reclaimed %d rx descriptors",
633 pdcs->pdc_idx, num_frags);
634
635 dev_dbg(dev,
636 "PDC %u txin %u, txout %u, rxin %u, rxout %u, last_rx_curr %u\n",
637 pdcs->pdc_idx, pdcs->txin, pdcs->txout, pdcs->rxin,
638 pdcs->rxout, pdcs->last_rx_curr);
639
640 if (pdcs->pdc_resp_hdr_len == PDC_SPUM_RESP_HDR_LEN) {
641 /*
642 * For SPU-M, get length of response msg and rx overflow status.
643 */
644 rx_status = *((u32 *)resp_hdr);
645 len = rx_status & RX_STATUS_LEN;
646 dev_dbg(dev,
647 "SPU response length %u bytes", len);
648 if (unlikely(((rx_status & RX_STATUS_OVERFLOW) || (!len)))) {
649 if (rx_status & RX_STATUS_OVERFLOW) {
650 dev_err_ratelimited(dev,
651 "crypto receive overflow");
652 pdcs->rx_oflow++;
653 } else {
654 dev_info_ratelimited(dev, "crypto rx len = 0");
655 }
656 return -EIO;
657 }
658 }
659
660 dma_pool_free(pdcs->rx_buf_pool, resp_hdr, resp_hdr_daddr);
661
662 mbox_chan_received_data(chan, &mssg);
663
664 pdcs->pdc_replies++;
665 return PDC_SUCCESS;
666 }
667
668 /**
669 * pdc_receive() - Process as many responses as are available in the rx ring.
670 * @pdcs: PDC state
671 *
672 * Called within the hard IRQ.
673 * Return:
674 */
675 static int
pdc_receive(struct pdc_state * pdcs)676 pdc_receive(struct pdc_state *pdcs)
677 {
678 int rx_status;
679
680 /* read last_rx_curr from register once */
681 pdcs->last_rx_curr =
682 (ioread32((const void __iomem *)&pdcs->rxregs_64->status0) &
683 CRYPTO_D64_RS0_CD_MASK) / RING_ENTRY_SIZE;
684
685 do {
686 /* Could be many frames ready */
687 rx_status = pdc_receive_one(pdcs);
688 } while (rx_status == PDC_SUCCESS);
689
690 return 0;
691 }
692
693 /**
694 * pdc_tx_list_sg_add() - Add the buffers in a scatterlist to the transmit
695 * descriptors for a given SPU. The scatterlist buffers contain the data for a
696 * SPU request message.
697 * @spu_idx: The index of the SPU to submit the request to, [0, max_spu)
698 * @sg: Scatterlist whose buffers contain part of the SPU request
699 *
700 * If a scatterlist buffer is larger than PDC_DMA_BUF_MAX, multiple descriptors
701 * are written for that buffer, each <= PDC_DMA_BUF_MAX byte in length.
702 *
703 * Return: PDC_SUCCESS if successful
704 * < 0 otherwise
705 */
pdc_tx_list_sg_add(struct pdc_state * pdcs,struct scatterlist * sg)706 static int pdc_tx_list_sg_add(struct pdc_state *pdcs, struct scatterlist *sg)
707 {
708 u32 flags = 0;
709 u32 eot;
710 u32 tx_avail;
711
712 /*
713 * Num descriptors needed. Conservatively assume we need a descriptor
714 * for every entry in sg.
715 */
716 u32 num_desc;
717 u32 desc_w = 0; /* Number of tx descriptors written */
718 u32 bufcnt; /* Number of bytes of buffer pointed to by descriptor */
719 dma_addr_t databufptr; /* DMA address to put in descriptor */
720
721 num_desc = (u32)sg_nents(sg);
722
723 /* check whether enough tx descriptors are available */
724 tx_avail = pdcs->ntxpost - NTXDACTIVE(pdcs->txin, pdcs->txout,
725 pdcs->ntxpost);
726 if (unlikely(num_desc > tx_avail)) {
727 pdcs->txnobuf++;
728 return -ENOSPC;
729 }
730
731 /* build tx descriptors */
732 if (pdcs->tx_msg_start == pdcs->txout) {
733 /* Start of frame */
734 pdcs->txin_numd[pdcs->tx_msg_start] = 0;
735 pdcs->src_sg[pdcs->txout] = sg;
736 flags = D64_CTRL1_SOF;
737 }
738
739 while (sg) {
740 if (unlikely(pdcs->txout == (pdcs->ntxd - 1)))
741 eot = D64_CTRL1_EOT;
742 else
743 eot = 0;
744
745 /*
746 * If sg buffer larger than PDC limit, split across
747 * multiple descriptors
748 */
749 bufcnt = sg_dma_len(sg);
750 databufptr = sg_dma_address(sg);
751 while (bufcnt > PDC_DMA_BUF_MAX) {
752 pdc_build_txd(pdcs, databufptr, PDC_DMA_BUF_MAX,
753 flags | eot);
754 desc_w++;
755 bufcnt -= PDC_DMA_BUF_MAX;
756 databufptr += PDC_DMA_BUF_MAX;
757 if (unlikely(pdcs->txout == (pdcs->ntxd - 1)))
758 eot = D64_CTRL1_EOT;
759 else
760 eot = 0;
761 }
762 sg = sg_next(sg);
763 if (!sg)
764 /* Writing last descriptor for frame */
765 flags |= (D64_CTRL1_EOF | D64_CTRL1_IOC);
766 pdc_build_txd(pdcs, databufptr, bufcnt, flags | eot);
767 desc_w++;
768 /* Clear start of frame after first descriptor */
769 flags &= ~D64_CTRL1_SOF;
770 }
771 pdcs->txin_numd[pdcs->tx_msg_start] += desc_w;
772
773 return PDC_SUCCESS;
774 }
775
776 /**
777 * pdc_tx_list_final() - Initiate DMA transfer of last frame written to tx
778 * ring.
779 * @pdcs: PDC state for SPU to process the request
780 *
781 * Sets the index of the last descriptor written in both the rx and tx ring.
782 *
783 * Return: PDC_SUCCESS
784 */
pdc_tx_list_final(struct pdc_state * pdcs)785 static int pdc_tx_list_final(struct pdc_state *pdcs)
786 {
787 /*
788 * write barrier to ensure all register writes are complete
789 * before chip starts to process new request
790 */
791 wmb();
792 iowrite32(pdcs->rxout << 4, &pdcs->rxregs_64->ptr);
793 iowrite32(pdcs->txout << 4, &pdcs->txregs_64->ptr);
794 pdcs->pdc_requests++;
795
796 return PDC_SUCCESS;
797 }
798
799 /**
800 * pdc_rx_list_init() - Start a new receive descriptor list for a given PDC.
801 * @pdcs: PDC state for SPU handling request
802 * @dst_sg: scatterlist providing rx buffers for response to be returned to
803 * mailbox client
804 * @ctx: Opaque context for this request
805 *
806 * Posts a single receive descriptor to hold the metadata that precedes a
807 * response. For example, with SPU-M, the metadata is a 32-byte DMA header and
808 * an 8-byte BCM header. Moves the msg_start descriptor indexes for both tx and
809 * rx to indicate the start of a new message.
810 *
811 * Return: PDC_SUCCESS if successful
812 * < 0 if an error (e.g., rx ring is full)
813 */
pdc_rx_list_init(struct pdc_state * pdcs,struct scatterlist * dst_sg,void * ctx)814 static int pdc_rx_list_init(struct pdc_state *pdcs, struct scatterlist *dst_sg,
815 void *ctx)
816 {
817 u32 flags = 0;
818 u32 rx_avail;
819 u32 rx_pkt_cnt = 1; /* Adding a single rx buffer */
820 dma_addr_t daddr;
821 void *vaddr;
822 struct pdc_rx_ctx *rx_ctx;
823
824 rx_avail = pdcs->nrxpost - NRXDACTIVE(pdcs->rxin, pdcs->rxout,
825 pdcs->nrxpost);
826 if (unlikely(rx_pkt_cnt > rx_avail)) {
827 pdcs->rxnobuf++;
828 return -ENOSPC;
829 }
830
831 /* allocate a buffer for the dma rx status */
832 vaddr = dma_pool_zalloc(pdcs->rx_buf_pool, GFP_ATOMIC, &daddr);
833 if (unlikely(!vaddr))
834 return -ENOMEM;
835
836 /*
837 * Update msg_start indexes for both tx and rx to indicate the start
838 * of a new sequence of descriptor indexes that contain the fragments
839 * of the same message.
840 */
841 pdcs->rx_msg_start = pdcs->rxout;
842 pdcs->tx_msg_start = pdcs->txout;
843
844 /* This is always the first descriptor in the receive sequence */
845 flags = D64_CTRL1_SOF;
846 pdcs->rx_ctx[pdcs->rx_msg_start].rxin_numd = 1;
847
848 if (unlikely(pdcs->rxout == (pdcs->nrxd - 1)))
849 flags |= D64_CTRL1_EOT;
850
851 rx_ctx = &pdcs->rx_ctx[pdcs->rxout];
852 rx_ctx->rxp_ctx = ctx;
853 rx_ctx->dst_sg = dst_sg;
854 rx_ctx->resp_hdr = vaddr;
855 rx_ctx->resp_hdr_daddr = daddr;
856 pdc_build_rxd(pdcs, daddr, pdcs->pdc_resp_hdr_len, flags);
857 return PDC_SUCCESS;
858 }
859
860 /**
861 * pdc_rx_list_sg_add() - Add the buffers in a scatterlist to the receive
862 * descriptors for a given SPU. The caller must have already DMA mapped the
863 * scatterlist.
864 * @spu_idx: Indicates which SPU the buffers are for
865 * @sg: Scatterlist whose buffers are added to the receive ring
866 *
867 * If a receive buffer in the scatterlist is larger than PDC_DMA_BUF_MAX,
868 * multiple receive descriptors are written, each with a buffer <=
869 * PDC_DMA_BUF_MAX.
870 *
871 * Return: PDC_SUCCESS if successful
872 * < 0 otherwise (e.g., receive ring is full)
873 */
pdc_rx_list_sg_add(struct pdc_state * pdcs,struct scatterlist * sg)874 static int pdc_rx_list_sg_add(struct pdc_state *pdcs, struct scatterlist *sg)
875 {
876 u32 flags = 0;
877 u32 rx_avail;
878
879 /*
880 * Num descriptors needed. Conservatively assume we need a descriptor
881 * for every entry from our starting point in the scatterlist.
882 */
883 u32 num_desc;
884 u32 desc_w = 0; /* Number of tx descriptors written */
885 u32 bufcnt; /* Number of bytes of buffer pointed to by descriptor */
886 dma_addr_t databufptr; /* DMA address to put in descriptor */
887
888 num_desc = (u32)sg_nents(sg);
889
890 rx_avail = pdcs->nrxpost - NRXDACTIVE(pdcs->rxin, pdcs->rxout,
891 pdcs->nrxpost);
892 if (unlikely(num_desc > rx_avail)) {
893 pdcs->rxnobuf++;
894 return -ENOSPC;
895 }
896
897 while (sg) {
898 if (unlikely(pdcs->rxout == (pdcs->nrxd - 1)))
899 flags = D64_CTRL1_EOT;
900 else
901 flags = 0;
902
903 /*
904 * If sg buffer larger than PDC limit, split across
905 * multiple descriptors
906 */
907 bufcnt = sg_dma_len(sg);
908 databufptr = sg_dma_address(sg);
909 while (bufcnt > PDC_DMA_BUF_MAX) {
910 pdc_build_rxd(pdcs, databufptr, PDC_DMA_BUF_MAX, flags);
911 desc_w++;
912 bufcnt -= PDC_DMA_BUF_MAX;
913 databufptr += PDC_DMA_BUF_MAX;
914 if (unlikely(pdcs->rxout == (pdcs->nrxd - 1)))
915 flags = D64_CTRL1_EOT;
916 else
917 flags = 0;
918 }
919 pdc_build_rxd(pdcs, databufptr, bufcnt, flags);
920 desc_w++;
921 sg = sg_next(sg);
922 }
923 pdcs->rx_ctx[pdcs->rx_msg_start].rxin_numd += desc_w;
924
925 return PDC_SUCCESS;
926 }
927
928 /**
929 * pdc_irq_handler() - Interrupt handler called in interrupt context.
930 * @irq: Interrupt number that has fired
931 * @data: device struct for DMA engine that generated the interrupt
932 *
933 * We have to clear the device interrupt status flags here. So cache the
934 * status for later use in the thread function. Other than that, just return
935 * WAKE_THREAD to invoke the thread function.
936 *
937 * Return: IRQ_WAKE_THREAD if interrupt is ours
938 * IRQ_NONE otherwise
939 */
pdc_irq_handler(int irq,void * data)940 static irqreturn_t pdc_irq_handler(int irq, void *data)
941 {
942 struct device *dev = (struct device *)data;
943 struct pdc_state *pdcs = dev_get_drvdata(dev);
944 u32 intstatus = ioread32(pdcs->pdc_reg_vbase + PDC_INTSTATUS_OFFSET);
945
946 if (unlikely(intstatus == 0))
947 return IRQ_NONE;
948
949 /* Disable interrupts until soft handler runs */
950 iowrite32(0, pdcs->pdc_reg_vbase + PDC_INTMASK_OFFSET);
951
952 /* Clear interrupt flags in device */
953 iowrite32(intstatus, pdcs->pdc_reg_vbase + PDC_INTSTATUS_OFFSET);
954
955 /* Wakeup IRQ thread */
956 tasklet_schedule(&pdcs->rx_tasklet);
957 return IRQ_HANDLED;
958 }
959
960 /**
961 * pdc_tasklet_cb() - Tasklet callback that runs the deferred processing after
962 * a DMA receive interrupt. Reenables the receive interrupt.
963 * @data: PDC state structure
964 */
pdc_tasklet_cb(struct tasklet_struct * t)965 static void pdc_tasklet_cb(struct tasklet_struct *t)
966 {
967 struct pdc_state *pdcs = from_tasklet(pdcs, t, rx_tasklet);
968
969 pdc_receive(pdcs);
970
971 /* reenable interrupts */
972 iowrite32(PDC_INTMASK, pdcs->pdc_reg_vbase + PDC_INTMASK_OFFSET);
973 }
974
975 /**
976 * pdc_ring_init() - Allocate DMA rings and initialize constant fields of
977 * descriptors in one ringset.
978 * @pdcs: PDC instance state
979 * @ringset: index of ringset being used
980 *
981 * Return: PDC_SUCCESS if ring initialized
982 * < 0 otherwise
983 */
pdc_ring_init(struct pdc_state * pdcs,int ringset)984 static int pdc_ring_init(struct pdc_state *pdcs, int ringset)
985 {
986 int i;
987 int err = PDC_SUCCESS;
988 struct dma64 *dma_reg;
989 struct device *dev = &pdcs->pdev->dev;
990 struct pdc_ring_alloc tx;
991 struct pdc_ring_alloc rx;
992
993 /* Allocate tx ring */
994 tx.vbase = dma_pool_zalloc(pdcs->ring_pool, GFP_KERNEL, &tx.dmabase);
995 if (unlikely(!tx.vbase)) {
996 err = -ENOMEM;
997 goto done;
998 }
999
1000 /* Allocate rx ring */
1001 rx.vbase = dma_pool_zalloc(pdcs->ring_pool, GFP_KERNEL, &rx.dmabase);
1002 if (unlikely(!rx.vbase)) {
1003 err = -ENOMEM;
1004 goto fail_dealloc;
1005 }
1006
1007 dev_dbg(dev, " - base DMA addr of tx ring %pad", &tx.dmabase);
1008 dev_dbg(dev, " - base virtual addr of tx ring %p", tx.vbase);
1009 dev_dbg(dev, " - base DMA addr of rx ring %pad", &rx.dmabase);
1010 dev_dbg(dev, " - base virtual addr of rx ring %p", rx.vbase);
1011
1012 memcpy(&pdcs->tx_ring_alloc, &tx, sizeof(tx));
1013 memcpy(&pdcs->rx_ring_alloc, &rx, sizeof(rx));
1014
1015 pdcs->rxin = 0;
1016 pdcs->rx_msg_start = 0;
1017 pdcs->last_rx_curr = 0;
1018 pdcs->rxout = 0;
1019 pdcs->txin = 0;
1020 pdcs->tx_msg_start = 0;
1021 pdcs->txout = 0;
1022
1023 /* Set descriptor array base addresses */
1024 pdcs->txd_64 = (struct dma64dd *)pdcs->tx_ring_alloc.vbase;
1025 pdcs->rxd_64 = (struct dma64dd *)pdcs->rx_ring_alloc.vbase;
1026
1027 /* Tell device the base DMA address of each ring */
1028 dma_reg = &pdcs->regs->dmaregs[ringset];
1029
1030 /* But first disable DMA and set curptr to 0 for both TX & RX */
1031 iowrite32(PDC_TX_CTL, &dma_reg->dmaxmt.control);
1032 iowrite32((PDC_RX_CTL + (pdcs->rx_status_len << 1)),
1033 &dma_reg->dmarcv.control);
1034 iowrite32(0, &dma_reg->dmaxmt.ptr);
1035 iowrite32(0, &dma_reg->dmarcv.ptr);
1036
1037 /* Set base DMA addresses */
1038 iowrite32(lower_32_bits(pdcs->tx_ring_alloc.dmabase),
1039 &dma_reg->dmaxmt.addrlow);
1040 iowrite32(upper_32_bits(pdcs->tx_ring_alloc.dmabase),
1041 &dma_reg->dmaxmt.addrhigh);
1042
1043 iowrite32(lower_32_bits(pdcs->rx_ring_alloc.dmabase),
1044 &dma_reg->dmarcv.addrlow);
1045 iowrite32(upper_32_bits(pdcs->rx_ring_alloc.dmabase),
1046 &dma_reg->dmarcv.addrhigh);
1047
1048 /* Re-enable DMA */
1049 iowrite32(PDC_TX_CTL | PDC_TX_ENABLE, &dma_reg->dmaxmt.control);
1050 iowrite32((PDC_RX_CTL | PDC_RX_ENABLE | (pdcs->rx_status_len << 1)),
1051 &dma_reg->dmarcv.control);
1052
1053 /* Initialize descriptors */
1054 for (i = 0; i < PDC_RING_ENTRIES; i++) {
1055 /* Every tx descriptor can be used for start of frame. */
1056 if (i != pdcs->ntxpost) {
1057 iowrite32(D64_CTRL1_SOF | D64_CTRL1_EOF,
1058 &pdcs->txd_64[i].ctrl1);
1059 } else {
1060 /* Last descriptor in ringset. Set End of Table. */
1061 iowrite32(D64_CTRL1_SOF | D64_CTRL1_EOF |
1062 D64_CTRL1_EOT, &pdcs->txd_64[i].ctrl1);
1063 }
1064
1065 /* Every rx descriptor can be used for start of frame */
1066 if (i != pdcs->nrxpost) {
1067 iowrite32(D64_CTRL1_SOF,
1068 &pdcs->rxd_64[i].ctrl1);
1069 } else {
1070 /* Last descriptor in ringset. Set End of Table. */
1071 iowrite32(D64_CTRL1_SOF | D64_CTRL1_EOT,
1072 &pdcs->rxd_64[i].ctrl1);
1073 }
1074 }
1075 return PDC_SUCCESS;
1076
1077 fail_dealloc:
1078 dma_pool_free(pdcs->ring_pool, tx.vbase, tx.dmabase);
1079 done:
1080 return err;
1081 }
1082
pdc_ring_free(struct pdc_state * pdcs)1083 static void pdc_ring_free(struct pdc_state *pdcs)
1084 {
1085 if (pdcs->tx_ring_alloc.vbase) {
1086 dma_pool_free(pdcs->ring_pool, pdcs->tx_ring_alloc.vbase,
1087 pdcs->tx_ring_alloc.dmabase);
1088 pdcs->tx_ring_alloc.vbase = NULL;
1089 }
1090
1091 if (pdcs->rx_ring_alloc.vbase) {
1092 dma_pool_free(pdcs->ring_pool, pdcs->rx_ring_alloc.vbase,
1093 pdcs->rx_ring_alloc.dmabase);
1094 pdcs->rx_ring_alloc.vbase = NULL;
1095 }
1096 }
1097
1098 /**
1099 * pdc_desc_count() - Count the number of DMA descriptors that will be required
1100 * for a given scatterlist. Account for the max length of a DMA buffer.
1101 * @sg: Scatterlist to be DMA'd
1102 * Return: Number of descriptors required
1103 */
pdc_desc_count(struct scatterlist * sg)1104 static u32 pdc_desc_count(struct scatterlist *sg)
1105 {
1106 u32 cnt = 0;
1107
1108 while (sg) {
1109 cnt += ((sg->length / PDC_DMA_BUF_MAX) + 1);
1110 sg = sg_next(sg);
1111 }
1112 return cnt;
1113 }
1114
1115 /**
1116 * pdc_rings_full() - Check whether the tx ring has room for tx_cnt descriptors
1117 * and the rx ring has room for rx_cnt descriptors.
1118 * @pdcs: PDC state
1119 * @tx_cnt: The number of descriptors required in the tx ring
1120 * @rx_cnt: The number of descriptors required i the rx ring
1121 *
1122 * Return: true if one of the rings does not have enough space
1123 * false if sufficient space is available in both rings
1124 */
pdc_rings_full(struct pdc_state * pdcs,int tx_cnt,int rx_cnt)1125 static bool pdc_rings_full(struct pdc_state *pdcs, int tx_cnt, int rx_cnt)
1126 {
1127 u32 rx_avail;
1128 u32 tx_avail;
1129 bool full = false;
1130
1131 /* Check if the tx and rx rings are likely to have enough space */
1132 rx_avail = pdcs->nrxpost - NRXDACTIVE(pdcs->rxin, pdcs->rxout,
1133 pdcs->nrxpost);
1134 if (unlikely(rx_cnt > rx_avail)) {
1135 pdcs->rx_ring_full++;
1136 full = true;
1137 }
1138
1139 if (likely(!full)) {
1140 tx_avail = pdcs->ntxpost - NTXDACTIVE(pdcs->txin, pdcs->txout,
1141 pdcs->ntxpost);
1142 if (unlikely(tx_cnt > tx_avail)) {
1143 pdcs->tx_ring_full++;
1144 full = true;
1145 }
1146 }
1147 return full;
1148 }
1149
1150 /**
1151 * pdc_last_tx_done() - If both the tx and rx rings have at least
1152 * PDC_RING_SPACE_MIN descriptors available, then indicate that the mailbox
1153 * framework can submit another message.
1154 * @chan: mailbox channel to check
1155 * Return: true if PDC can accept another message on this channel
1156 */
pdc_last_tx_done(struct mbox_chan * chan)1157 static bool pdc_last_tx_done(struct mbox_chan *chan)
1158 {
1159 struct pdc_state *pdcs = chan->con_priv;
1160 bool ret;
1161
1162 if (unlikely(pdc_rings_full(pdcs, PDC_RING_SPACE_MIN,
1163 PDC_RING_SPACE_MIN))) {
1164 pdcs->last_tx_not_done++;
1165 ret = false;
1166 } else {
1167 ret = true;
1168 }
1169 return ret;
1170 }
1171
1172 /**
1173 * pdc_send_data() - mailbox send_data function
1174 * @chan: The mailbox channel on which the data is sent. The channel
1175 * corresponds to a DMA ringset.
1176 * @data: The mailbox message to be sent. The message must be a
1177 * brcm_message structure.
1178 *
1179 * This function is registered as the send_data function for the mailbox
1180 * controller. From the destination scatterlist in the mailbox message, it
1181 * creates a sequence of receive descriptors in the rx ring. From the source
1182 * scatterlist, it creates a sequence of transmit descriptors in the tx ring.
1183 * After creating the descriptors, it writes the rx ptr and tx ptr registers to
1184 * initiate the DMA transfer.
1185 *
1186 * This function does the DMA map and unmap of the src and dst scatterlists in
1187 * the mailbox message.
1188 *
1189 * Return: 0 if successful
1190 * -ENOTSUPP if the mailbox message is a type this driver does not
1191 * support
1192 * < 0 if an error
1193 */
pdc_send_data(struct mbox_chan * chan,void * data)1194 static int pdc_send_data(struct mbox_chan *chan, void *data)
1195 {
1196 struct pdc_state *pdcs = chan->con_priv;
1197 struct device *dev = &pdcs->pdev->dev;
1198 struct brcm_message *mssg = data;
1199 int err = PDC_SUCCESS;
1200 int src_nent;
1201 int dst_nent;
1202 int nent;
1203 u32 tx_desc_req;
1204 u32 rx_desc_req;
1205
1206 if (unlikely(mssg->type != BRCM_MESSAGE_SPU))
1207 return -ENOTSUPP;
1208
1209 src_nent = sg_nents(mssg->spu.src);
1210 if (likely(src_nent)) {
1211 nent = dma_map_sg(dev, mssg->spu.src, src_nent, DMA_TO_DEVICE);
1212 if (unlikely(nent == 0))
1213 return -EIO;
1214 }
1215
1216 dst_nent = sg_nents(mssg->spu.dst);
1217 if (likely(dst_nent)) {
1218 nent = dma_map_sg(dev, mssg->spu.dst, dst_nent,
1219 DMA_FROM_DEVICE);
1220 if (unlikely(nent == 0)) {
1221 dma_unmap_sg(dev, mssg->spu.src, src_nent,
1222 DMA_TO_DEVICE);
1223 return -EIO;
1224 }
1225 }
1226
1227 /*
1228 * Check if the tx and rx rings have enough space. Do this prior to
1229 * writing any tx or rx descriptors. Need to ensure that we do not write
1230 * a partial set of descriptors, or write just rx descriptors but
1231 * corresponding tx descriptors don't fit. Note that we want this check
1232 * and the entire sequence of descriptor to happen without another
1233 * thread getting in. The channel spin lock in the mailbox framework
1234 * ensures this.
1235 */
1236 tx_desc_req = pdc_desc_count(mssg->spu.src);
1237 rx_desc_req = pdc_desc_count(mssg->spu.dst);
1238 if (unlikely(pdc_rings_full(pdcs, tx_desc_req, rx_desc_req + 1)))
1239 return -ENOSPC;
1240
1241 /* Create rx descriptors to SPU catch response */
1242 err = pdc_rx_list_init(pdcs, mssg->spu.dst, mssg->ctx);
1243 err |= pdc_rx_list_sg_add(pdcs, mssg->spu.dst);
1244
1245 /* Create tx descriptors to submit SPU request */
1246 err |= pdc_tx_list_sg_add(pdcs, mssg->spu.src);
1247 err |= pdc_tx_list_final(pdcs); /* initiate transfer */
1248
1249 if (unlikely(err))
1250 dev_err(&pdcs->pdev->dev,
1251 "%s failed with error %d", __func__, err);
1252
1253 return err;
1254 }
1255
pdc_startup(struct mbox_chan * chan)1256 static int pdc_startup(struct mbox_chan *chan)
1257 {
1258 return pdc_ring_init(chan->con_priv, PDC_RINGSET);
1259 }
1260
pdc_shutdown(struct mbox_chan * chan)1261 static void pdc_shutdown(struct mbox_chan *chan)
1262 {
1263 struct pdc_state *pdcs = chan->con_priv;
1264
1265 if (!pdcs)
1266 return;
1267
1268 dev_dbg(&pdcs->pdev->dev,
1269 "Shutdown mailbox channel for PDC %u", pdcs->pdc_idx);
1270 pdc_ring_free(pdcs);
1271 }
1272
1273 /**
1274 * pdc_hw_init() - Use the given initialization parameters to initialize the
1275 * state for one of the PDCs.
1276 * @pdcs: state of the PDC
1277 */
1278 static
pdc_hw_init(struct pdc_state * pdcs)1279 void pdc_hw_init(struct pdc_state *pdcs)
1280 {
1281 struct platform_device *pdev;
1282 struct device *dev;
1283 struct dma64 *dma_reg;
1284 int ringset = PDC_RINGSET;
1285
1286 pdev = pdcs->pdev;
1287 dev = &pdev->dev;
1288
1289 dev_dbg(dev, "PDC %u initial values:", pdcs->pdc_idx);
1290 dev_dbg(dev, "state structure: %p",
1291 pdcs);
1292 dev_dbg(dev, " - base virtual addr of hw regs %p",
1293 pdcs->pdc_reg_vbase);
1294
1295 /* initialize data structures */
1296 pdcs->regs = (struct pdc_regs *)pdcs->pdc_reg_vbase;
1297 pdcs->txregs_64 = (struct dma64_regs *)
1298 (((u8 *)pdcs->pdc_reg_vbase) +
1299 PDC_TXREGS_OFFSET + (sizeof(struct dma64) * ringset));
1300 pdcs->rxregs_64 = (struct dma64_regs *)
1301 (((u8 *)pdcs->pdc_reg_vbase) +
1302 PDC_RXREGS_OFFSET + (sizeof(struct dma64) * ringset));
1303
1304 pdcs->ntxd = PDC_RING_ENTRIES;
1305 pdcs->nrxd = PDC_RING_ENTRIES;
1306 pdcs->ntxpost = PDC_RING_ENTRIES - 1;
1307 pdcs->nrxpost = PDC_RING_ENTRIES - 1;
1308 iowrite32(0, &pdcs->regs->intmask);
1309
1310 dma_reg = &pdcs->regs->dmaregs[ringset];
1311
1312 /* Configure DMA but will enable later in pdc_ring_init() */
1313 iowrite32(PDC_TX_CTL, &dma_reg->dmaxmt.control);
1314
1315 iowrite32(PDC_RX_CTL + (pdcs->rx_status_len << 1),
1316 &dma_reg->dmarcv.control);
1317
1318 /* Reset current index pointers after making sure DMA is disabled */
1319 iowrite32(0, &dma_reg->dmaxmt.ptr);
1320 iowrite32(0, &dma_reg->dmarcv.ptr);
1321
1322 if (pdcs->pdc_resp_hdr_len == PDC_SPU2_RESP_HDR_LEN)
1323 iowrite32(PDC_CKSUM_CTRL,
1324 pdcs->pdc_reg_vbase + PDC_CKSUM_CTRL_OFFSET);
1325 }
1326
1327 /**
1328 * pdc_hw_disable() - Disable the tx and rx control in the hw.
1329 * @pdcs: PDC state structure
1330 *
1331 */
pdc_hw_disable(struct pdc_state * pdcs)1332 static void pdc_hw_disable(struct pdc_state *pdcs)
1333 {
1334 struct dma64 *dma_reg;
1335
1336 dma_reg = &pdcs->regs->dmaregs[PDC_RINGSET];
1337 iowrite32(PDC_TX_CTL, &dma_reg->dmaxmt.control);
1338 iowrite32(PDC_RX_CTL + (pdcs->rx_status_len << 1),
1339 &dma_reg->dmarcv.control);
1340 }
1341
1342 /**
1343 * pdc_rx_buf_pool_create() - Pool of receive buffers used to catch the metadata
1344 * header returned with each response message.
1345 * @pdcs: PDC state structure
1346 *
1347 * The metadata is not returned to the mailbox client. So the PDC driver
1348 * manages these buffers.
1349 *
1350 * Return: PDC_SUCCESS
1351 * -ENOMEM if pool creation fails
1352 */
pdc_rx_buf_pool_create(struct pdc_state * pdcs)1353 static int pdc_rx_buf_pool_create(struct pdc_state *pdcs)
1354 {
1355 struct platform_device *pdev;
1356 struct device *dev;
1357
1358 pdev = pdcs->pdev;
1359 dev = &pdev->dev;
1360
1361 pdcs->pdc_resp_hdr_len = pdcs->rx_status_len;
1362 if (pdcs->use_bcm_hdr)
1363 pdcs->pdc_resp_hdr_len += BCM_HDR_LEN;
1364
1365 pdcs->rx_buf_pool = dma_pool_create("pdc rx bufs", dev,
1366 pdcs->pdc_resp_hdr_len,
1367 RX_BUF_ALIGN, 0);
1368 if (!pdcs->rx_buf_pool)
1369 return -ENOMEM;
1370
1371 return PDC_SUCCESS;
1372 }
1373
1374 /**
1375 * pdc_interrupts_init() - Initialize the interrupt configuration for a PDC and
1376 * specify a threaded IRQ handler for deferred handling of interrupts outside of
1377 * interrupt context.
1378 * @pdcs: PDC state
1379 *
1380 * Set the interrupt mask for transmit and receive done.
1381 * Set the lazy interrupt frame count to generate an interrupt for just one pkt.
1382 *
1383 * Return: PDC_SUCCESS
1384 * <0 if threaded irq request fails
1385 */
pdc_interrupts_init(struct pdc_state * pdcs)1386 static int pdc_interrupts_init(struct pdc_state *pdcs)
1387 {
1388 struct platform_device *pdev = pdcs->pdev;
1389 struct device *dev = &pdev->dev;
1390 struct device_node *dn = pdev->dev.of_node;
1391 int err;
1392
1393 /* interrupt configuration */
1394 iowrite32(PDC_INTMASK, pdcs->pdc_reg_vbase + PDC_INTMASK_OFFSET);
1395
1396 if (pdcs->hw_type == FA_HW)
1397 iowrite32(PDC_LAZY_INT, pdcs->pdc_reg_vbase +
1398 FA_RCVLAZY0_OFFSET);
1399 else
1400 iowrite32(PDC_LAZY_INT, pdcs->pdc_reg_vbase +
1401 PDC_RCVLAZY0_OFFSET);
1402
1403 /* read irq from device tree */
1404 pdcs->pdc_irq = irq_of_parse_and_map(dn, 0);
1405 dev_dbg(dev, "pdc device %s irq %u for pdcs %p",
1406 dev_name(dev), pdcs->pdc_irq, pdcs);
1407
1408 err = devm_request_irq(dev, pdcs->pdc_irq, pdc_irq_handler, 0,
1409 dev_name(dev), dev);
1410 if (err) {
1411 dev_err(dev, "IRQ %u request failed with err %d\n",
1412 pdcs->pdc_irq, err);
1413 return err;
1414 }
1415 return PDC_SUCCESS;
1416 }
1417
1418 static const struct mbox_chan_ops pdc_mbox_chan_ops = {
1419 .send_data = pdc_send_data,
1420 .last_tx_done = pdc_last_tx_done,
1421 .startup = pdc_startup,
1422 .shutdown = pdc_shutdown
1423 };
1424
1425 /**
1426 * pdc_mb_init() - Initialize the mailbox controller.
1427 * @pdcs: PDC state
1428 *
1429 * Each PDC is a mailbox controller. Each ringset is a mailbox channel. Kernel
1430 * driver only uses one ringset and thus one mb channel. PDC uses the transmit
1431 * complete interrupt to determine when a mailbox message has successfully been
1432 * transmitted.
1433 *
1434 * Return: 0 on success
1435 * < 0 if there is an allocation or registration failure
1436 */
pdc_mb_init(struct pdc_state * pdcs)1437 static int pdc_mb_init(struct pdc_state *pdcs)
1438 {
1439 struct device *dev = &pdcs->pdev->dev;
1440 struct mbox_controller *mbc;
1441 int chan_index;
1442 int err;
1443
1444 mbc = &pdcs->mbc;
1445 mbc->dev = dev;
1446 mbc->ops = &pdc_mbox_chan_ops;
1447 mbc->num_chans = 1;
1448 mbc->chans = devm_kcalloc(dev, mbc->num_chans, sizeof(*mbc->chans),
1449 GFP_KERNEL);
1450 if (!mbc->chans)
1451 return -ENOMEM;
1452
1453 mbc->txdone_irq = false;
1454 mbc->txdone_poll = true;
1455 mbc->txpoll_period = 1;
1456 for (chan_index = 0; chan_index < mbc->num_chans; chan_index++)
1457 mbc->chans[chan_index].con_priv = pdcs;
1458
1459 /* Register mailbox controller */
1460 err = devm_mbox_controller_register(dev, mbc);
1461 if (err) {
1462 dev_crit(dev,
1463 "Failed to register PDC mailbox controller. Error %d.",
1464 err);
1465 return err;
1466 }
1467 return 0;
1468 }
1469
1470 /* Device tree API */
1471 static const int pdc_hw = PDC_HW;
1472 static const int fa_hw = FA_HW;
1473
1474 static const struct of_device_id pdc_mbox_of_match[] = {
1475 {.compatible = "brcm,iproc-pdc-mbox", .data = &pdc_hw},
1476 {.compatible = "brcm,iproc-fa2-mbox", .data = &fa_hw},
1477 { /* sentinel */ }
1478 };
1479 MODULE_DEVICE_TABLE(of, pdc_mbox_of_match);
1480
1481 /**
1482 * pdc_dt_read() - Read application-specific data from device tree.
1483 * @pdev: Platform device
1484 * @pdcs: PDC state
1485 *
1486 * Reads the number of bytes of receive status that precede each received frame.
1487 * Reads whether transmit and received frames should be preceded by an 8-byte
1488 * BCM header.
1489 *
1490 * Return: 0 if successful
1491 * -ENODEV if device not available
1492 */
pdc_dt_read(struct platform_device * pdev,struct pdc_state * pdcs)1493 static int pdc_dt_read(struct platform_device *pdev, struct pdc_state *pdcs)
1494 {
1495 struct device *dev = &pdev->dev;
1496 struct device_node *dn = pdev->dev.of_node;
1497 const struct of_device_id *match;
1498 const int *hw_type;
1499 int err;
1500
1501 err = of_property_read_u32(dn, "brcm,rx-status-len",
1502 &pdcs->rx_status_len);
1503 if (err < 0)
1504 dev_err(dev,
1505 "%s failed to get DMA receive status length from device tree",
1506 __func__);
1507
1508 pdcs->use_bcm_hdr = of_property_read_bool(dn, "brcm,use-bcm-hdr");
1509
1510 pdcs->hw_type = PDC_HW;
1511
1512 match = of_match_device(of_match_ptr(pdc_mbox_of_match), dev);
1513 if (match != NULL) {
1514 hw_type = match->data;
1515 pdcs->hw_type = *hw_type;
1516 }
1517
1518 return 0;
1519 }
1520
1521 /**
1522 * pdc_probe() - Probe function for PDC driver.
1523 * @pdev: PDC platform device
1524 *
1525 * Reserve and map register regions defined in device tree.
1526 * Allocate and initialize tx and rx DMA rings.
1527 * Initialize a mailbox controller for each PDC.
1528 *
1529 * Return: 0 if successful
1530 * < 0 if an error
1531 */
pdc_probe(struct platform_device * pdev)1532 static int pdc_probe(struct platform_device *pdev)
1533 {
1534 int err = 0;
1535 struct device *dev = &pdev->dev;
1536 struct resource *pdc_regs;
1537 struct pdc_state *pdcs;
1538
1539 /* PDC state for one SPU */
1540 pdcs = devm_kzalloc(dev, sizeof(*pdcs), GFP_KERNEL);
1541 if (!pdcs) {
1542 err = -ENOMEM;
1543 goto cleanup;
1544 }
1545
1546 pdcs->pdev = pdev;
1547 platform_set_drvdata(pdev, pdcs);
1548 pdcs->pdc_idx = pdcg.num_spu;
1549 pdcg.num_spu++;
1550
1551 err = dma_set_mask_and_coherent(dev, DMA_BIT_MASK(39));
1552 if (err) {
1553 dev_warn(dev, "PDC device cannot perform DMA. Error %d.", err);
1554 goto cleanup;
1555 }
1556
1557 /* Create DMA pool for tx ring */
1558 pdcs->ring_pool = dma_pool_create("pdc rings", dev, PDC_RING_SIZE,
1559 RING_ALIGN, 0);
1560 if (!pdcs->ring_pool) {
1561 err = -ENOMEM;
1562 goto cleanup;
1563 }
1564
1565 err = pdc_dt_read(pdev, pdcs);
1566 if (err)
1567 goto cleanup_ring_pool;
1568
1569 pdc_regs = platform_get_resource(pdev, IORESOURCE_MEM, 0);
1570 if (!pdc_regs) {
1571 err = -ENODEV;
1572 goto cleanup_ring_pool;
1573 }
1574 dev_dbg(dev, "PDC register region res.start = %pa, res.end = %pa",
1575 &pdc_regs->start, &pdc_regs->end);
1576
1577 pdcs->pdc_reg_vbase = devm_ioremap_resource(&pdev->dev, pdc_regs);
1578 if (IS_ERR(pdcs->pdc_reg_vbase)) {
1579 err = PTR_ERR(pdcs->pdc_reg_vbase);
1580 goto cleanup_ring_pool;
1581 }
1582
1583 /* create rx buffer pool after dt read to know how big buffers are */
1584 err = pdc_rx_buf_pool_create(pdcs);
1585 if (err)
1586 goto cleanup_ring_pool;
1587
1588 pdc_hw_init(pdcs);
1589
1590 /* Init tasklet for deferred DMA rx processing */
1591 tasklet_setup(&pdcs->rx_tasklet, pdc_tasklet_cb);
1592
1593 err = pdc_interrupts_init(pdcs);
1594 if (err)
1595 goto cleanup_buf_pool;
1596
1597 /* Initialize mailbox controller */
1598 err = pdc_mb_init(pdcs);
1599 if (err)
1600 goto cleanup_buf_pool;
1601
1602 pdc_setup_debugfs(pdcs);
1603
1604 dev_dbg(dev, "pdc_probe() successful");
1605 return PDC_SUCCESS;
1606
1607 cleanup_buf_pool:
1608 tasklet_kill(&pdcs->rx_tasklet);
1609 dma_pool_destroy(pdcs->rx_buf_pool);
1610
1611 cleanup_ring_pool:
1612 dma_pool_destroy(pdcs->ring_pool);
1613
1614 cleanup:
1615 return err;
1616 }
1617
pdc_remove(struct platform_device * pdev)1618 static int pdc_remove(struct platform_device *pdev)
1619 {
1620 struct pdc_state *pdcs = platform_get_drvdata(pdev);
1621
1622 pdc_free_debugfs();
1623
1624 tasklet_kill(&pdcs->rx_tasklet);
1625
1626 pdc_hw_disable(pdcs);
1627
1628 dma_pool_destroy(pdcs->rx_buf_pool);
1629 dma_pool_destroy(pdcs->ring_pool);
1630 return 0;
1631 }
1632
1633 static struct platform_driver pdc_mbox_driver = {
1634 .probe = pdc_probe,
1635 .remove = pdc_remove,
1636 .driver = {
1637 .name = "brcm-iproc-pdc-mbox",
1638 .of_match_table = of_match_ptr(pdc_mbox_of_match),
1639 },
1640 };
1641 module_platform_driver(pdc_mbox_driver);
1642
1643 MODULE_AUTHOR("Rob Rice <rob.rice@broadcom.com>");
1644 MODULE_DESCRIPTION("Broadcom PDC mailbox driver");
1645 MODULE_LICENSE("GPL v2");
1646