spi-topcliff-pch: add recovery processing in case wait-event timeout
[zen-stable.git] / drivers / staging / crystalhd / crystalhd_hw.c
blob5acf39e7cdef730b7d55a4d19bb0c219759d7051
1 /***************************************************************************
2 * Copyright (c) 2005-2009, Broadcom Corporation.
4 * Name: crystalhd_hw . c
6 * Description:
7 * BCM70010 Linux driver HW layer.
9 **********************************************************************
10 * This file is part of the crystalhd device driver.
12 * This driver is free software; you can redistribute it and/or modify
13 * it under the terms of the GNU General Public License as published by
14 * the Free Software Foundation, version 2 of the License.
16 * This driver is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 * GNU General Public License for more details.
21 * You should have received a copy of the GNU General Public License
22 * along with this driver. If not, see <http://www.gnu.org/licenses/>.
23 **********************************************************************/
25 #include <linux/pci.h>
26 #include <linux/slab.h>
27 #include <linux/delay.h>
28 #include "crystalhd_hw.h"
30 /* Functions internal to this file */
32 static void crystalhd_enable_uarts(struct crystalhd_adp *adp)
34 bc_dec_reg_wr(adp, UartSelectA, BSVS_UART_STREAM);
35 bc_dec_reg_wr(adp, UartSelectB, BSVS_UART_DEC_OUTER);
39 static void crystalhd_start_dram(struct crystalhd_adp *adp)
41 bc_dec_reg_wr(adp, SDRAM_PARAM, ((40 / 5 - 1) << 0) |
42 /* tras (40ns tras)/(5ns period) -1 ((15/5 - 1) << 4) | // trcd */
43 ((15 / 5 - 1) << 7) | /* trp */
44 ((10 / 5 - 1) << 10) | /* trrd */
45 ((15 / 5 + 1) << 12) | /* twr */
46 ((2 + 1) << 16) | /* twtr */
47 ((70 / 5 - 2) << 19) | /* trfc */
48 (0 << 23));
50 bc_dec_reg_wr(adp, SDRAM_PRECHARGE, 0);
51 bc_dec_reg_wr(adp, SDRAM_EXT_MODE, 2);
52 bc_dec_reg_wr(adp, SDRAM_MODE, 0x132);
53 bc_dec_reg_wr(adp, SDRAM_PRECHARGE, 0);
54 bc_dec_reg_wr(adp, SDRAM_REFRESH, 0);
55 bc_dec_reg_wr(adp, SDRAM_REFRESH, 0);
56 bc_dec_reg_wr(adp, SDRAM_MODE, 0x32);
57 /* setting the refresh rate here */
58 bc_dec_reg_wr(adp, SDRAM_REF_PARAM, ((1 << 12) | 96));
62 static bool crystalhd_bring_out_of_rst(struct crystalhd_adp *adp)
64 union link_misc_perst_deco_ctrl rst_deco_cntrl;
65 union link_misc_perst_clk_ctrl rst_clk_cntrl;
66 uint32_t temp;
69 * Link clocks: MISC_PERST_CLOCK_CTRL Clear PLL power down bit,
70 * delay to allow PLL to lock Clear alternate clock, stop clock bits
72 rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
73 rst_clk_cntrl.pll_pwr_dn = 0;
74 crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
75 msleep_interruptible(50);
77 rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
78 rst_clk_cntrl.stop_core_clk = 0;
79 rst_clk_cntrl.sel_alt_clk = 0;
81 crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
82 msleep_interruptible(50);
85 * Bus Arbiter Timeout: GISB_ARBITER_TIMER
86 * Set internal bus arbiter timeout to 40us based on core clock speed
87 * (63MHz * 40us = 0x9D8)
89 crystalhd_reg_wr(adp, GISB_ARBITER_TIMER, 0x9D8);
92 * Decoder clocks: MISC_PERST_DECODER_CTRL
93 * Enable clocks while 7412 reset is asserted, delay
94 * De-assert 7412 reset
96 rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_DECODER_CTRL);
97 rst_deco_cntrl.stop_bcm_7412_clk = 0;
98 rst_deco_cntrl.bcm7412_rst = 1;
99 crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL, rst_deco_cntrl.whole_reg);
100 msleep_interruptible(10);
102 rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_DECODER_CTRL);
103 rst_deco_cntrl.bcm7412_rst = 0;
104 crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL, rst_deco_cntrl.whole_reg);
105 msleep_interruptible(50);
107 /* Disable OTP_CONTENT_MISC to 0 to disable all secure modes */
108 crystalhd_reg_wr(adp, OTP_CONTENT_MISC, 0);
110 /* Clear bit 29 of 0x404 */
111 temp = crystalhd_reg_rd(adp, PCIE_TL_TRANSACTION_CONFIGURATION);
112 temp &= ~BC_BIT(29);
113 crystalhd_reg_wr(adp, PCIE_TL_TRANSACTION_CONFIGURATION, temp);
115 /* 2.5V regulator must be set to 2.6 volts (+6%) */
116 /* FIXME: jarod: what's the point of this reg read? */
117 temp = crystalhd_reg_rd(adp, MISC_PERST_VREG_CTRL);
118 crystalhd_reg_wr(adp, MISC_PERST_VREG_CTRL, 0xF3);
120 return true;
123 static bool crystalhd_put_in_reset(struct crystalhd_adp *adp)
125 union link_misc_perst_deco_ctrl rst_deco_cntrl;
126 union link_misc_perst_clk_ctrl rst_clk_cntrl;
127 uint32_t temp;
130 * Decoder clocks: MISC_PERST_DECODER_CTRL
131 * Assert 7412 reset, delay
132 * Assert 7412 stop clock
134 rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_DECODER_CTRL);
135 rst_deco_cntrl.stop_bcm_7412_clk = 1;
136 crystalhd_reg_wr(adp, MISC_PERST_DECODER_CTRL, rst_deco_cntrl.whole_reg);
137 msleep_interruptible(50);
139 /* Bus Arbiter Timeout: GISB_ARBITER_TIMER
140 * Set internal bus arbiter timeout to 40us based on core clock speed
141 * (6.75MHZ * 40us = 0x10E)
143 crystalhd_reg_wr(adp, GISB_ARBITER_TIMER, 0x10E);
145 /* Link clocks: MISC_PERST_CLOCK_CTRL
146 * Stop core clk, delay
147 * Set alternate clk, delay, set PLL power down
149 rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
150 rst_clk_cntrl.stop_core_clk = 1;
151 rst_clk_cntrl.sel_alt_clk = 1;
152 crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
153 msleep_interruptible(50);
155 rst_clk_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC_PERST_CLOCK_CTRL);
156 rst_clk_cntrl.pll_pwr_dn = 1;
157 crystalhd_reg_wr(adp, MISC_PERST_CLOCK_CTRL, rst_clk_cntrl.whole_reg);
160 * Read and restore the Transaction Configuration Register
161 * after core reset
163 temp = crystalhd_reg_rd(adp, PCIE_TL_TRANSACTION_CONFIGURATION);
166 * Link core soft reset: MISC3_RESET_CTRL
167 * - Write BIT[0]=1 and read it back for core reset to take place
169 crystalhd_reg_wr(adp, MISC3_RESET_CTRL, 1);
170 rst_deco_cntrl.whole_reg = crystalhd_reg_rd(adp, MISC3_RESET_CTRL);
171 msleep_interruptible(50);
173 /* restore the transaction configuration register */
174 crystalhd_reg_wr(adp, PCIE_TL_TRANSACTION_CONFIGURATION, temp);
176 return true;
179 static void crystalhd_disable_interrupts(struct crystalhd_adp *adp)
181 union intr_mask_reg intr_mask;
182 intr_mask.whole_reg = crystalhd_reg_rd(adp, INTR_INTR_MSK_STS_REG);
183 intr_mask.mask_pcie_err = 1;
184 intr_mask.mask_pcie_rbusmast_err = 1;
185 intr_mask.mask_pcie_rgr_bridge = 1;
186 intr_mask.mask_rx_done = 1;
187 intr_mask.mask_rx_err = 1;
188 intr_mask.mask_tx_done = 1;
189 intr_mask.mask_tx_err = 1;
190 crystalhd_reg_wr(adp, INTR_INTR_MSK_SET_REG, intr_mask.whole_reg);
192 return;
195 static void crystalhd_enable_interrupts(struct crystalhd_adp *adp)
197 union intr_mask_reg intr_mask;
198 intr_mask.whole_reg = crystalhd_reg_rd(adp, INTR_INTR_MSK_STS_REG);
199 intr_mask.mask_pcie_err = 1;
200 intr_mask.mask_pcie_rbusmast_err = 1;
201 intr_mask.mask_pcie_rgr_bridge = 1;
202 intr_mask.mask_rx_done = 1;
203 intr_mask.mask_rx_err = 1;
204 intr_mask.mask_tx_done = 1;
205 intr_mask.mask_tx_err = 1;
206 crystalhd_reg_wr(adp, INTR_INTR_MSK_CLR_REG, intr_mask.whole_reg);
208 return;
211 static void crystalhd_clear_errors(struct crystalhd_adp *adp)
213 uint32_t reg;
215 /* FIXME: jarod: wouldn't we want to write a 0 to the reg? Or does the write clear the bits specified? */
216 reg = crystalhd_reg_rd(adp, MISC1_Y_RX_ERROR_STATUS);
217 if (reg)
218 crystalhd_reg_wr(adp, MISC1_Y_RX_ERROR_STATUS, reg);
220 reg = crystalhd_reg_rd(adp, MISC1_UV_RX_ERROR_STATUS);
221 if (reg)
222 crystalhd_reg_wr(adp, MISC1_UV_RX_ERROR_STATUS, reg);
224 reg = crystalhd_reg_rd(adp, MISC1_TX_DMA_ERROR_STATUS);
225 if (reg)
226 crystalhd_reg_wr(adp, MISC1_TX_DMA_ERROR_STATUS, reg);
229 static void crystalhd_clear_interrupts(struct crystalhd_adp *adp)
231 uint32_t intr_sts = crystalhd_reg_rd(adp, INTR_INTR_STATUS);
233 if (intr_sts) {
234 crystalhd_reg_wr(adp, INTR_INTR_CLR_REG, intr_sts);
236 /* Write End Of Interrupt for PCIE */
237 crystalhd_reg_wr(adp, INTR_EOI_CTRL, 1);
241 static void crystalhd_soft_rst(struct crystalhd_adp *adp)
243 uint32_t val;
245 /* Assert c011 soft reset*/
246 bc_dec_reg_wr(adp, DecHt_HostSwReset, 0x00000001);
247 msleep_interruptible(50);
249 /* Release c011 soft reset*/
250 bc_dec_reg_wr(adp, DecHt_HostSwReset, 0x00000000);
252 /* Disable Stuffing..*/
253 val = crystalhd_reg_rd(adp, MISC2_GLOBAL_CTRL);
254 val |= BC_BIT(8);
255 crystalhd_reg_wr(adp, MISC2_GLOBAL_CTRL, val);
258 static bool crystalhd_load_firmware_config(struct crystalhd_adp *adp)
260 uint32_t i = 0, reg;
262 crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (BC_DRAM_FW_CFG_ADDR >> 19));
264 crystalhd_reg_wr(adp, AES_CMD, 0);
265 crystalhd_reg_wr(adp, AES_CONFIG_INFO, (BC_DRAM_FW_CFG_ADDR & 0x7FFFF));
266 crystalhd_reg_wr(adp, AES_CMD, 0x1);
268 /* FIXME: jarod: I've seen this fail, and introducing extra delays helps... */
269 for (i = 0; i < 100; ++i) {
270 reg = crystalhd_reg_rd(adp, AES_STATUS);
271 if (reg & 0x1)
272 return true;
273 msleep_interruptible(10);
276 return false;
280 static bool crystalhd_start_device(struct crystalhd_adp *adp)
282 uint32_t dbg_options, glb_cntrl = 0, reg_pwrmgmt = 0;
284 BCMLOG(BCMLOG_INFO, "Starting BCM70012 Device\n");
286 reg_pwrmgmt = crystalhd_reg_rd(adp, PCIE_DLL_DATA_LINK_CONTROL);
287 reg_pwrmgmt &= ~ASPM_L1_ENABLE;
289 crystalhd_reg_wr(adp, PCIE_DLL_DATA_LINK_CONTROL, reg_pwrmgmt);
291 if (!crystalhd_bring_out_of_rst(adp)) {
292 BCMLOG_ERR("Failed To Bring Link Out Of Reset\n");
293 return false;
296 crystalhd_disable_interrupts(adp);
298 crystalhd_clear_errors(adp);
300 crystalhd_clear_interrupts(adp);
302 crystalhd_enable_interrupts(adp);
304 /* Enable the option for getting the total no. of DWORDS
305 * that have been transferred by the RXDMA engine
307 dbg_options = crystalhd_reg_rd(adp, MISC1_DMA_DEBUG_OPTIONS_REG);
308 dbg_options |= 0x10;
309 crystalhd_reg_wr(adp, MISC1_DMA_DEBUG_OPTIONS_REG, dbg_options);
311 /* Enable PCI Global Control options */
312 glb_cntrl = crystalhd_reg_rd(adp, MISC2_GLOBAL_CTRL);
313 glb_cntrl |= 0x100;
314 glb_cntrl |= 0x8000;
315 crystalhd_reg_wr(adp, MISC2_GLOBAL_CTRL, glb_cntrl);
317 crystalhd_enable_interrupts(adp);
319 crystalhd_soft_rst(adp);
320 crystalhd_start_dram(adp);
321 crystalhd_enable_uarts(adp);
323 return true;
326 static bool crystalhd_stop_device(struct crystalhd_adp *adp)
328 uint32_t reg;
330 BCMLOG(BCMLOG_INFO, "Stopping BCM70012 Device\n");
331 /* Clear and disable interrupts */
332 crystalhd_disable_interrupts(adp);
333 crystalhd_clear_errors(adp);
334 crystalhd_clear_interrupts(adp);
336 if (!crystalhd_put_in_reset(adp))
337 BCMLOG_ERR("Failed to Put Link To Reset State\n");
339 reg = crystalhd_reg_rd(adp, PCIE_DLL_DATA_LINK_CONTROL);
340 reg |= ASPM_L1_ENABLE;
341 crystalhd_reg_wr(adp, PCIE_DLL_DATA_LINK_CONTROL, reg);
343 /* Set PCI Clk Req */
344 reg = crystalhd_reg_rd(adp, PCIE_CLK_REQ_REG);
345 reg |= PCI_CLK_REQ_ENABLE;
346 crystalhd_reg_wr(adp, PCIE_CLK_REQ_REG, reg);
348 return true;
351 static struct crystalhd_rx_dma_pkt *crystalhd_hw_alloc_rx_pkt(struct crystalhd_hw *hw)
353 unsigned long flags = 0;
354 struct crystalhd_rx_dma_pkt *temp = NULL;
356 if (!hw)
357 return NULL;
359 spin_lock_irqsave(&hw->lock, flags);
360 temp = hw->rx_pkt_pool_head;
361 if (temp) {
362 hw->rx_pkt_pool_head = hw->rx_pkt_pool_head->next;
363 temp->dio_req = NULL;
364 temp->pkt_tag = 0;
365 temp->flags = 0;
367 spin_unlock_irqrestore(&hw->lock, flags);
369 return temp;
372 static void crystalhd_hw_free_rx_pkt(struct crystalhd_hw *hw,
373 struct crystalhd_rx_dma_pkt *pkt)
375 unsigned long flags = 0;
377 if (!hw || !pkt)
378 return;
380 spin_lock_irqsave(&hw->lock, flags);
381 pkt->next = hw->rx_pkt_pool_head;
382 hw->rx_pkt_pool_head = pkt;
383 spin_unlock_irqrestore(&hw->lock, flags);
387 * Call back from TX - IOQ deletion.
389 * This routine will release the TX DMA rings allocated
390 * druing setup_dma rings interface.
392 * Memory is allocated per DMA ring basis. This is just
393 * a place holder to be able to create the dio queues.
395 static void crystalhd_tx_desc_rel_call_back(void *context, void *data)
400 * Rx Packet release callback..
402 * Release All user mapped capture buffers and Our DMA packets
403 * back to our free pool. The actual cleanup of the DMA
404 * ring descriptors happen during dma ring release.
406 static void crystalhd_rx_pkt_rel_call_back(void *context, void *data)
408 struct crystalhd_hw *hw = (struct crystalhd_hw *)context;
409 struct crystalhd_rx_dma_pkt *pkt = (struct crystalhd_rx_dma_pkt *)data;
411 if (!pkt || !hw) {
412 BCMLOG_ERR("Invalid arg - %p %p\n", hw, pkt);
413 return;
416 if (pkt->dio_req)
417 crystalhd_unmap_dio(hw->adp, pkt->dio_req);
418 else
419 BCMLOG_ERR("Missing dio_req: 0x%x\n", pkt->pkt_tag);
421 crystalhd_hw_free_rx_pkt(hw, pkt);
424 #define crystalhd_hw_delete_ioq(adp, q) \
425 if (q) { \
426 crystalhd_delete_dioq(adp, q); \
427 q = NULL; \
430 static void crystalhd_hw_delete_ioqs(struct crystalhd_hw *hw)
432 if (!hw)
433 return;
435 BCMLOG(BCMLOG_DBG, "Deleting IOQs\n");
436 crystalhd_hw_delete_ioq(hw->adp, hw->tx_actq);
437 crystalhd_hw_delete_ioq(hw->adp, hw->tx_freeq);
438 crystalhd_hw_delete_ioq(hw->adp, hw->rx_actq);
439 crystalhd_hw_delete_ioq(hw->adp, hw->rx_freeq);
440 crystalhd_hw_delete_ioq(hw->adp, hw->rx_rdyq);
443 #define crystalhd_hw_create_ioq(sts, hw, q, cb) \
444 do { \
445 sts = crystalhd_create_dioq(hw->adp, &q, cb, hw); \
446 if (sts != BC_STS_SUCCESS) \
447 goto hw_create_ioq_err; \
448 } while (0)
451 * Create IOQs..
453 * TX - Active & Free
454 * RX - Active, Ready and Free.
456 static enum BC_STATUS crystalhd_hw_create_ioqs(struct crystalhd_hw *hw)
458 enum BC_STATUS sts = BC_STS_SUCCESS;
460 if (!hw) {
461 BCMLOG_ERR("Invalid Arg!!\n");
462 return BC_STS_INV_ARG;
465 crystalhd_hw_create_ioq(sts, hw, hw->tx_freeq,
466 crystalhd_tx_desc_rel_call_back);
467 crystalhd_hw_create_ioq(sts, hw, hw->tx_actq,
468 crystalhd_tx_desc_rel_call_back);
470 crystalhd_hw_create_ioq(sts, hw, hw->rx_freeq,
471 crystalhd_rx_pkt_rel_call_back);
472 crystalhd_hw_create_ioq(sts, hw, hw->rx_rdyq,
473 crystalhd_rx_pkt_rel_call_back);
474 crystalhd_hw_create_ioq(sts, hw, hw->rx_actq,
475 crystalhd_rx_pkt_rel_call_back);
477 return sts;
479 hw_create_ioq_err:
480 crystalhd_hw_delete_ioqs(hw);
482 return sts;
486 static bool crystalhd_code_in_full(struct crystalhd_adp *adp, uint32_t needed_sz,
487 bool b_188_byte_pkts, uint8_t flags)
489 uint32_t base, end, writep, readp;
490 uint32_t cpbSize, cpbFullness, fifoSize;
492 if (flags & 0x02) { /* ASF Bit is set */
493 base = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Base);
494 end = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2End);
495 writep = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Wrptr);
496 readp = bc_dec_reg_rd(adp, REG_Dec_TsAudCDB2Rdptr);
497 } else if (b_188_byte_pkts) { /*Encrypted 188 byte packets*/
498 base = bc_dec_reg_rd(adp, REG_Dec_TsUser0Base);
499 end = bc_dec_reg_rd(adp, REG_Dec_TsUser0End);
500 writep = bc_dec_reg_rd(adp, REG_Dec_TsUser0Wrptr);
501 readp = bc_dec_reg_rd(adp, REG_Dec_TsUser0Rdptr);
502 } else {
503 base = bc_dec_reg_rd(adp, REG_DecCA_RegCinBase);
504 end = bc_dec_reg_rd(adp, REG_DecCA_RegCinEnd);
505 writep = bc_dec_reg_rd(adp, REG_DecCA_RegCinWrPtr);
506 readp = bc_dec_reg_rd(adp, REG_DecCA_RegCinRdPtr);
509 cpbSize = end - base;
510 if (writep >= readp)
511 cpbFullness = writep - readp;
512 else
513 cpbFullness = (end - base) - (readp - writep);
515 fifoSize = cpbSize - cpbFullness;
517 if (fifoSize < BC_INFIFO_THRESHOLD)
518 return true;
520 if (needed_sz > (fifoSize - BC_INFIFO_THRESHOLD))
521 return true;
523 return false;
526 static enum BC_STATUS crystalhd_hw_tx_req_complete(struct crystalhd_hw *hw,
527 uint32_t list_id, enum BC_STATUS cs)
529 struct tx_dma_pkt *tx_req;
531 if (!hw || !list_id) {
532 BCMLOG_ERR("Invalid Arg..\n");
533 return BC_STS_INV_ARG;
536 hw->pwr_lock--;
538 tx_req = (struct tx_dma_pkt *)crystalhd_dioq_find_and_fetch(hw->tx_actq, list_id);
539 if (!tx_req) {
540 if (cs != BC_STS_IO_USER_ABORT)
541 BCMLOG_ERR("Find and Fetch Did not find req\n");
542 return BC_STS_NO_DATA;
545 if (tx_req->call_back) {
546 tx_req->call_back(tx_req->dio_req, tx_req->cb_event, cs);
547 tx_req->dio_req = NULL;
548 tx_req->cb_event = NULL;
549 tx_req->call_back = NULL;
550 } else {
551 BCMLOG(BCMLOG_DBG, "Missing Tx Callback - %X\n",
552 tx_req->list_tag);
555 /* Now put back the tx_list back in FreeQ */
556 tx_req->list_tag = 0;
558 return crystalhd_dioq_add(hw->tx_freeq, tx_req, false, 0);
561 static bool crystalhd_tx_list0_handler(struct crystalhd_hw *hw, uint32_t err_sts)
563 uint32_t err_mask, tmp;
564 unsigned long flags = 0;
566 err_mask = MISC1_TX_DMA_ERROR_STATUS_TX_L0_DESC_TX_ABORT_ERRORS_MASK |
567 MISC1_TX_DMA_ERROR_STATUS_TX_L0_DMA_DATA_TX_ABORT_ERRORS_MASK |
568 MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK;
570 if (!(err_sts & err_mask))
571 return false;
573 BCMLOG_ERR("Error on Tx-L0 %x\n", err_sts);
575 tmp = err_mask;
577 if (err_sts & MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK)
578 tmp &= ~MISC1_TX_DMA_ERROR_STATUS_TX_L0_FIFO_FULL_ERRORS_MASK;
580 if (tmp) {
581 spin_lock_irqsave(&hw->lock, flags);
582 /* reset list index.*/
583 hw->tx_list_post_index = 0;
584 spin_unlock_irqrestore(&hw->lock, flags);
587 tmp = err_sts & err_mask;
588 crystalhd_reg_wr(hw->adp, MISC1_TX_DMA_ERROR_STATUS, tmp);
590 return true;
593 static bool crystalhd_tx_list1_handler(struct crystalhd_hw *hw, uint32_t err_sts)
595 uint32_t err_mask, tmp;
596 unsigned long flags = 0;
598 err_mask = MISC1_TX_DMA_ERROR_STATUS_TX_L1_DESC_TX_ABORT_ERRORS_MASK |
599 MISC1_TX_DMA_ERROR_STATUS_TX_L1_DMA_DATA_TX_ABORT_ERRORS_MASK |
600 MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK;
602 if (!(err_sts & err_mask))
603 return false;
605 BCMLOG_ERR("Error on Tx-L1 %x\n", err_sts);
607 tmp = err_mask;
609 if (err_sts & MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK)
610 tmp &= ~MISC1_TX_DMA_ERROR_STATUS_TX_L1_FIFO_FULL_ERRORS_MASK;
612 if (tmp) {
613 spin_lock_irqsave(&hw->lock, flags);
614 /* reset list index.*/
615 hw->tx_list_post_index = 0;
616 spin_unlock_irqrestore(&hw->lock, flags);
619 tmp = err_sts & err_mask;
620 crystalhd_reg_wr(hw->adp, MISC1_TX_DMA_ERROR_STATUS, tmp);
622 return true;
625 static void crystalhd_tx_isr(struct crystalhd_hw *hw, uint32_t int_sts)
627 uint32_t err_sts;
629 if (int_sts & INTR_INTR_STATUS_L0_TX_DMA_DONE_INTR_MASK)
630 crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 0,
631 BC_STS_SUCCESS);
633 if (int_sts & INTR_INTR_STATUS_L1_TX_DMA_DONE_INTR_MASK)
634 crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 1,
635 BC_STS_SUCCESS);
637 if (!(int_sts & (INTR_INTR_STATUS_L0_TX_DMA_ERR_INTR_MASK |
638 INTR_INTR_STATUS_L1_TX_DMA_ERR_INTR_MASK))) {
639 /* No error mask set.. */
640 return;
643 /* Handle Tx errors. */
644 err_sts = crystalhd_reg_rd(hw->adp, MISC1_TX_DMA_ERROR_STATUS);
646 if (crystalhd_tx_list0_handler(hw, err_sts))
647 crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 0,
648 BC_STS_ERROR);
650 if (crystalhd_tx_list1_handler(hw, err_sts))
651 crystalhd_hw_tx_req_complete(hw, hw->tx_ioq_tag_seed + 1,
652 BC_STS_ERROR);
654 hw->stats.tx_errors++;
657 static void crystalhd_hw_dump_desc(struct dma_descriptor *p_dma_desc,
658 uint32_t ul_desc_index, uint32_t cnt)
660 uint32_t ix, ll = 0;
662 if (!p_dma_desc || !cnt)
663 return;
665 /* FIXME: jarod: perhaps a modparam desc_debug to enable this, rather than
666 * setting ll (log level, I presume) to non-zero? */
667 if (!ll)
668 return;
670 for (ix = ul_desc_index; ix < (ul_desc_index + cnt); ix++) {
671 BCMLOG(ll, "%s[%d] Buff[%x:%x] Next:[%x:%x] XferSz:%x Intr:%x,Last:%x\n",
672 ((p_dma_desc[ul_desc_index].dma_dir) ? "TDesc" : "RDesc"),
673 ul_desc_index,
674 p_dma_desc[ul_desc_index].buff_addr_high,
675 p_dma_desc[ul_desc_index].buff_addr_low,
676 p_dma_desc[ul_desc_index].next_desc_addr_high,
677 p_dma_desc[ul_desc_index].next_desc_addr_low,
678 p_dma_desc[ul_desc_index].xfer_size,
679 p_dma_desc[ul_desc_index].intr_enable,
680 p_dma_desc[ul_desc_index].last_rec_indicator);
685 static enum BC_STATUS crystalhd_hw_fill_desc(struct crystalhd_dio_req *ioreq,
686 struct dma_descriptor *desc,
687 dma_addr_t desc_paddr_base,
688 uint32_t sg_cnt, uint32_t sg_st_ix,
689 uint32_t sg_st_off, uint32_t xfr_sz)
691 uint32_t count = 0, ix = 0, sg_ix = 0, len = 0, last_desc_ix = 0;
692 dma_addr_t desc_phy_addr = desc_paddr_base;
693 union addr_64 addr_temp;
695 if (!ioreq || !desc || !desc_paddr_base || !xfr_sz ||
696 (!sg_cnt && !ioreq->uinfo.dir_tx)) {
697 BCMLOG_ERR("Invalid Args\n");
698 return BC_STS_INV_ARG;
701 for (ix = 0; ix < sg_cnt; ix++) {
703 /* Setup SGLE index. */
704 sg_ix = ix + sg_st_ix;
706 /* Get SGLE length */
707 len = crystalhd_get_sgle_len(ioreq, sg_ix);
708 if (len % 4) {
709 BCMLOG_ERR(" len in sg %d %d %d\n", len, sg_ix, sg_cnt);
710 return BC_STS_NOT_IMPL;
712 /* Setup DMA desc with Phy addr & Length at current index. */
713 addr_temp.full_addr = crystalhd_get_sgle_paddr(ioreq, sg_ix);
714 if (sg_ix == sg_st_ix) {
715 addr_temp.full_addr += sg_st_off;
716 len -= sg_st_off;
718 memset(&desc[ix], 0, sizeof(desc[ix]));
719 desc[ix].buff_addr_low = addr_temp.low_part;
720 desc[ix].buff_addr_high = addr_temp.high_part;
721 desc[ix].dma_dir = ioreq->uinfo.dir_tx;
723 /* Chain DMA descriptor. */
724 addr_temp.full_addr = desc_phy_addr + sizeof(struct dma_descriptor);
725 desc[ix].next_desc_addr_low = addr_temp.low_part;
726 desc[ix].next_desc_addr_high = addr_temp.high_part;
728 if ((count + len) > xfr_sz)
729 len = xfr_sz - count;
731 /* Debug.. */
732 if ((!len) || (len > crystalhd_get_sgle_len(ioreq, sg_ix))) {
733 BCMLOG_ERR("inv-len(%x) Ix(%d) count:%x xfr_sz:%x sg_cnt:%d\n",
734 len, ix, count, xfr_sz, sg_cnt);
735 return BC_STS_ERROR;
737 /* Length expects Multiple of 4 */
738 desc[ix].xfer_size = (len / 4);
740 crystalhd_hw_dump_desc(desc, ix, 1);
742 count += len;
743 desc_phy_addr += sizeof(struct dma_descriptor);
746 last_desc_ix = ix - 1;
748 if (ioreq->fb_size) {
749 memset(&desc[ix], 0, sizeof(desc[ix]));
750 addr_temp.full_addr = ioreq->fb_pa;
751 desc[ix].buff_addr_low = addr_temp.low_part;
752 desc[ix].buff_addr_high = addr_temp.high_part;
753 desc[ix].dma_dir = ioreq->uinfo.dir_tx;
754 desc[ix].xfer_size = 1;
755 desc[ix].fill_bytes = 4 - ioreq->fb_size;
756 count += ioreq->fb_size;
757 last_desc_ix++;
760 /* setup last descriptor..*/
761 desc[last_desc_ix].last_rec_indicator = 1;
762 desc[last_desc_ix].next_desc_addr_low = 0;
763 desc[last_desc_ix].next_desc_addr_high = 0;
764 desc[last_desc_ix].intr_enable = 1;
766 crystalhd_hw_dump_desc(desc, last_desc_ix, 1);
768 if (count != xfr_sz) {
769 BCMLOG_ERR("interal error sz curr:%x exp:%x\n", count, xfr_sz);
770 return BC_STS_ERROR;
773 return BC_STS_SUCCESS;
776 static enum BC_STATUS crystalhd_xlat_sgl_to_dma_desc(struct crystalhd_dio_req *ioreq,
777 struct dma_desc_mem *pdesc_mem,
778 uint32_t *uv_desc_index)
780 struct dma_descriptor *desc = NULL;
781 dma_addr_t desc_paddr_base = 0;
782 uint32_t sg_cnt = 0, sg_st_ix = 0, sg_st_off = 0;
783 uint32_t xfr_sz = 0;
784 enum BC_STATUS sts = BC_STS_SUCCESS;
786 /* Check params.. */
787 if (!ioreq || !pdesc_mem || !uv_desc_index) {
788 BCMLOG_ERR("Invalid Args\n");
789 return BC_STS_INV_ARG;
792 if (!pdesc_mem->sz || !pdesc_mem->pdma_desc_start ||
793 !ioreq->sg || (!ioreq->sg_cnt && !ioreq->uinfo.dir_tx)) {
794 BCMLOG_ERR("Invalid Args\n");
795 return BC_STS_INV_ARG;
798 if ((ioreq->uinfo.dir_tx) && (ioreq->uinfo.uv_offset)) {
799 BCMLOG_ERR("UV offset for TX??\n");
800 return BC_STS_INV_ARG;
804 desc = pdesc_mem->pdma_desc_start;
805 desc_paddr_base = pdesc_mem->phy_addr;
807 if (ioreq->uinfo.dir_tx || (ioreq->uinfo.uv_offset == 0)) {
808 sg_cnt = ioreq->sg_cnt;
809 xfr_sz = ioreq->uinfo.xfr_len;
810 } else {
811 sg_cnt = ioreq->uinfo.uv_sg_ix + 1;
812 xfr_sz = ioreq->uinfo.uv_offset;
815 sts = crystalhd_hw_fill_desc(ioreq, desc, desc_paddr_base, sg_cnt,
816 sg_st_ix, sg_st_off, xfr_sz);
818 if ((sts != BC_STS_SUCCESS) || !ioreq->uinfo.uv_offset)
819 return sts;
821 /* Prepare for UV mapping.. */
822 desc = &pdesc_mem->pdma_desc_start[sg_cnt];
823 desc_paddr_base = pdesc_mem->phy_addr +
824 (sg_cnt * sizeof(struct dma_descriptor));
826 /* Done with desc addr.. now update sg stuff.*/
827 sg_cnt = ioreq->sg_cnt - ioreq->uinfo.uv_sg_ix;
828 xfr_sz = ioreq->uinfo.xfr_len - ioreq->uinfo.uv_offset;
829 sg_st_ix = ioreq->uinfo.uv_sg_ix;
830 sg_st_off = ioreq->uinfo.uv_sg_off;
832 sts = crystalhd_hw_fill_desc(ioreq, desc, desc_paddr_base, sg_cnt,
833 sg_st_ix, sg_st_off, xfr_sz);
834 if (sts != BC_STS_SUCCESS)
835 return sts;
837 *uv_desc_index = sg_st_ix;
839 return sts;
842 static void crystalhd_start_tx_dma_engine(struct crystalhd_hw *hw)
844 uint32_t dma_cntrl;
846 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS);
847 if (!(dma_cntrl & DMA_START_BIT)) {
848 dma_cntrl |= DMA_START_BIT;
849 crystalhd_reg_wr(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS,
850 dma_cntrl);
853 return;
856 /* _CHECK_THIS_
858 * Verify if the Stop generates a completion interrupt or not.
859 * if it does not generate an interrupt, then add polling here.
861 static enum BC_STATUS crystalhd_stop_tx_dma_engine(struct crystalhd_hw *hw)
863 uint32_t dma_cntrl, cnt = 30;
864 uint32_t l1 = 1, l2 = 1;
865 unsigned long flags = 0;
867 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS);
869 BCMLOG(BCMLOG_DBG, "Stopping TX DMA Engine..\n");
871 /* FIXME: jarod: invert dma_ctrl and check bit? or are there missing parens? */
872 if (!dma_cntrl & DMA_START_BIT) {
873 BCMLOG(BCMLOG_DBG, "Already Stopped\n");
874 return BC_STS_SUCCESS;
877 crystalhd_disable_interrupts(hw->adp);
879 /* Issue stop to HW */
880 /* This bit when set gave problems. Please check*/
881 dma_cntrl &= ~DMA_START_BIT;
882 crystalhd_reg_wr(hw->adp, MISC1_TX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
884 BCMLOG(BCMLOG_DBG, "Cleared the DMA Start bit\n");
886 /* Poll for 3seconds (30 * 100ms) on both the lists..*/
887 while ((l1 || l2) && cnt) {
889 if (l1) {
890 l1 = crystalhd_reg_rd(hw->adp, MISC1_TX_FIRST_DESC_L_ADDR_LIST0);
891 l1 &= DMA_START_BIT;
894 if (l2) {
895 l2 = crystalhd_reg_rd(hw->adp, MISC1_TX_FIRST_DESC_L_ADDR_LIST1);
896 l2 &= DMA_START_BIT;
899 msleep_interruptible(100);
901 cnt--;
904 if (!cnt) {
905 BCMLOG_ERR("Failed to stop TX DMA.. l1 %d, l2 %d\n", l1, l2);
906 crystalhd_enable_interrupts(hw->adp);
907 return BC_STS_ERROR;
910 spin_lock_irqsave(&hw->lock, flags);
911 hw->tx_list_post_index = 0;
912 spin_unlock_irqrestore(&hw->lock, flags);
913 BCMLOG(BCMLOG_DBG, "stopped TX DMA..\n");
914 crystalhd_enable_interrupts(hw->adp);
916 return BC_STS_SUCCESS;
919 static uint32_t crystalhd_get_pib_avail_cnt(struct crystalhd_hw *hw)
922 * Position of the PIB Entries can be found at
923 * 0th and the 1st location of the Circular list.
925 uint32_t Q_addr;
926 uint32_t pib_cnt, r_offset, w_offset;
928 Q_addr = hw->pib_del_Q_addr;
930 /* Get the Read Pointer */
931 crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
933 /* Get the Write Pointer */
934 crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
936 if (r_offset == w_offset)
937 return 0; /* Queue is empty */
939 if (w_offset > r_offset)
940 pib_cnt = w_offset - r_offset;
941 else
942 pib_cnt = (w_offset + MAX_PIB_Q_DEPTH) -
943 (r_offset + MIN_PIB_Q_DEPTH);
945 if (pib_cnt > MAX_PIB_Q_DEPTH) {
946 BCMLOG_ERR("Invalid PIB Count (%u)\n", pib_cnt);
947 return 0;
950 return pib_cnt;
953 static uint32_t crystalhd_get_addr_from_pib_Q(struct crystalhd_hw *hw)
955 uint32_t Q_addr;
956 uint32_t addr_entry, r_offset, w_offset;
958 Q_addr = hw->pib_del_Q_addr;
960 /* Get the Read Pointer 0Th Location is Read Pointer */
961 crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
963 /* Get the Write Pointer 1st Location is Write pointer */
964 crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
966 /* Queue is empty */
967 if (r_offset == w_offset)
968 return 0;
970 if ((r_offset < MIN_PIB_Q_DEPTH) || (r_offset >= MAX_PIB_Q_DEPTH))
971 return 0;
973 /* Get the Actual Address of the PIB */
974 crystalhd_mem_rd(hw->adp, Q_addr + (r_offset * sizeof(uint32_t)),
975 1, &addr_entry);
977 /* Increment the Read Pointer */
978 r_offset++;
980 if (MAX_PIB_Q_DEPTH == r_offset)
981 r_offset = MIN_PIB_Q_DEPTH;
983 /* Write back the read pointer to It's Location */
984 crystalhd_mem_wr(hw->adp, Q_addr, 1, &r_offset);
986 return addr_entry;
989 static bool crystalhd_rel_addr_to_pib_Q(struct crystalhd_hw *hw, uint32_t addr_to_rel)
991 uint32_t Q_addr;
992 uint32_t r_offset, w_offset, n_offset;
994 Q_addr = hw->pib_rel_Q_addr;
996 /* Get the Read Pointer */
997 crystalhd_mem_rd(hw->adp, Q_addr, 1, &r_offset);
999 /* Get the Write Pointer */
1000 crystalhd_mem_rd(hw->adp, Q_addr + sizeof(uint32_t), 1, &w_offset);
1002 if ((r_offset < MIN_PIB_Q_DEPTH) ||
1003 (r_offset >= MAX_PIB_Q_DEPTH))
1004 return false;
1006 n_offset = w_offset + 1;
1008 if (MAX_PIB_Q_DEPTH == n_offset)
1009 n_offset = MIN_PIB_Q_DEPTH;
1011 if (r_offset == n_offset)
1012 return false; /* should never happen */
1014 /* Write the DRAM ADDR to the Queue at Next Offset */
1015 crystalhd_mem_wr(hw->adp, Q_addr + (w_offset * sizeof(uint32_t)),
1016 1, &addr_to_rel);
1018 /* Put the New value of the write pointer in Queue */
1019 crystalhd_mem_wr(hw->adp, Q_addr + sizeof(uint32_t), 1, &n_offset);
1021 return true;
1024 static void cpy_pib_to_app(struct c011_pib *src_pib, struct BC_PIC_INFO_BLOCK *dst_pib)
1026 if (!src_pib || !dst_pib) {
1027 BCMLOG_ERR("Invalid Arguments\n");
1028 return;
1031 dst_pib->timeStamp = 0;
1032 dst_pib->picture_number = src_pib->ppb.picture_number;
1033 dst_pib->width = src_pib->ppb.width;
1034 dst_pib->height = src_pib->ppb.height;
1035 dst_pib->chroma_format = src_pib->ppb.chroma_format;
1036 dst_pib->pulldown = src_pib->ppb.pulldown;
1037 dst_pib->flags = src_pib->ppb.flags;
1038 dst_pib->sess_num = src_pib->ptsStcOffset;
1039 dst_pib->aspect_ratio = src_pib->ppb.aspect_ratio;
1040 dst_pib->colour_primaries = src_pib->ppb.colour_primaries;
1041 dst_pib->picture_meta_payload = src_pib->ppb.picture_meta_payload;
1042 dst_pib->frame_rate = src_pib->resolution ;
1043 return;
1046 static void crystalhd_hw_proc_pib(struct crystalhd_hw *hw)
1048 unsigned int cnt;
1049 struct c011_pib src_pib;
1050 uint32_t pib_addr, pib_cnt;
1051 struct BC_PIC_INFO_BLOCK *AppPib;
1052 struct crystalhd_rx_dma_pkt *rx_pkt = NULL;
1054 pib_cnt = crystalhd_get_pib_avail_cnt(hw);
1056 if (!pib_cnt)
1057 return;
1059 for (cnt = 0; cnt < pib_cnt; cnt++) {
1061 pib_addr = crystalhd_get_addr_from_pib_Q(hw);
1062 crystalhd_mem_rd(hw->adp, pib_addr, sizeof(struct c011_pib) / 4,
1063 (uint32_t *)&src_pib);
1065 if (src_pib.bFormatChange) {
1066 rx_pkt = (struct crystalhd_rx_dma_pkt *)crystalhd_dioq_fetch(hw->rx_freeq);
1067 if (!rx_pkt)
1068 return;
1069 rx_pkt->flags = 0;
1070 rx_pkt->flags |= COMP_FLAG_PIB_VALID | COMP_FLAG_FMT_CHANGE;
1071 AppPib = &rx_pkt->pib;
1072 cpy_pib_to_app(&src_pib, AppPib);
1074 BCMLOG(BCMLOG_DBG,
1075 "App PIB:%x %x %x %x %x %x %x %x %x %x\n",
1076 rx_pkt->pib.picture_number,
1077 rx_pkt->pib.aspect_ratio,
1078 rx_pkt->pib.chroma_format,
1079 rx_pkt->pib.colour_primaries,
1080 rx_pkt->pib.frame_rate,
1081 rx_pkt->pib.height,
1082 rx_pkt->pib.height,
1083 rx_pkt->pib.n_drop,
1084 rx_pkt->pib.pulldown,
1085 rx_pkt->pib.ycom);
1087 crystalhd_dioq_add(hw->rx_rdyq, (void *)rx_pkt, true, rx_pkt->pkt_tag);
1091 crystalhd_rel_addr_to_pib_Q(hw, pib_addr);
1095 static void crystalhd_start_rx_dma_engine(struct crystalhd_hw *hw)
1097 uint32_t dma_cntrl;
1099 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
1100 if (!(dma_cntrl & DMA_START_BIT)) {
1101 dma_cntrl |= DMA_START_BIT;
1102 crystalhd_reg_wr(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1105 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
1106 if (!(dma_cntrl & DMA_START_BIT)) {
1107 dma_cntrl |= DMA_START_BIT;
1108 crystalhd_reg_wr(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1111 return;
1114 static void crystalhd_stop_rx_dma_engine(struct crystalhd_hw *hw)
1116 uint32_t dma_cntrl = 0, count = 30;
1117 uint32_t l0y = 1, l0uv = 1, l1y = 1, l1uv = 1;
1119 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
1120 if ((dma_cntrl & DMA_START_BIT)) {
1121 dma_cntrl &= ~DMA_START_BIT;
1122 crystalhd_reg_wr(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1125 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
1126 if ((dma_cntrl & DMA_START_BIT)) {
1127 dma_cntrl &= ~DMA_START_BIT;
1128 crystalhd_reg_wr(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1131 /* Poll for 3seconds (30 * 100ms) on both the lists..*/
1132 while ((l0y || l0uv || l1y || l1uv) && count) {
1134 if (l0y) {
1135 l0y = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST0);
1136 l0y &= DMA_START_BIT;
1137 if (!l0y)
1138 hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
1141 if (l1y) {
1142 l1y = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST1);
1143 l1y &= DMA_START_BIT;
1144 if (!l1y)
1145 hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
1148 if (l0uv) {
1149 l0uv = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST0);
1150 l0uv &= DMA_START_BIT;
1151 if (!l0uv)
1152 hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
1155 if (l1uv) {
1156 l1uv = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST1);
1157 l1uv &= DMA_START_BIT;
1158 if (!l1uv)
1159 hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
1161 msleep_interruptible(100);
1162 count--;
1165 hw->rx_list_post_index = 0;
1167 BCMLOG(BCMLOG_SSTEP, "Capture Stop: %d List0:Sts:%x List1:Sts:%x\n",
1168 count, hw->rx_list_sts[0], hw->rx_list_sts[1]);
1171 static enum BC_STATUS crystalhd_hw_prog_rxdma(struct crystalhd_hw *hw, struct crystalhd_rx_dma_pkt *rx_pkt)
1173 uint32_t y_low_addr_reg, y_high_addr_reg;
1174 uint32_t uv_low_addr_reg, uv_high_addr_reg;
1175 union addr_64 desc_addr;
1176 unsigned long flags;
1178 if (!hw || !rx_pkt) {
1179 BCMLOG_ERR("Invalid Arguments\n");
1180 return BC_STS_INV_ARG;
1183 if (hw->rx_list_post_index >= DMA_ENGINE_CNT) {
1184 BCMLOG_ERR("List Out Of bounds %x\n", hw->rx_list_post_index);
1185 return BC_STS_INV_ARG;
1188 spin_lock_irqsave(&hw->rx_lock, flags);
1189 /* FIXME: jarod: sts_free is an enum for 0, in crystalhd_hw.h... yuk... */
1190 if (sts_free != hw->rx_list_sts[hw->rx_list_post_index]) {
1191 spin_unlock_irqrestore(&hw->rx_lock, flags);
1192 return BC_STS_BUSY;
1195 if (!hw->rx_list_post_index) {
1196 y_low_addr_reg = MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST0;
1197 y_high_addr_reg = MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST0;
1198 uv_low_addr_reg = MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST0;
1199 uv_high_addr_reg = MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST0;
1200 } else {
1201 y_low_addr_reg = MISC1_Y_RX_FIRST_DESC_L_ADDR_LIST1;
1202 y_high_addr_reg = MISC1_Y_RX_FIRST_DESC_U_ADDR_LIST1;
1203 uv_low_addr_reg = MISC1_UV_RX_FIRST_DESC_L_ADDR_LIST1;
1204 uv_high_addr_reg = MISC1_UV_RX_FIRST_DESC_U_ADDR_LIST1;
1206 rx_pkt->pkt_tag = hw->rx_pkt_tag_seed + hw->rx_list_post_index;
1207 hw->rx_list_sts[hw->rx_list_post_index] |= rx_waiting_y_intr;
1208 if (rx_pkt->uv_phy_addr)
1209 hw->rx_list_sts[hw->rx_list_post_index] |= rx_waiting_uv_intr;
1210 hw->rx_list_post_index = (hw->rx_list_post_index + 1) % DMA_ENGINE_CNT;
1211 spin_unlock_irqrestore(&hw->rx_lock, flags);
1213 crystalhd_dioq_add(hw->rx_actq, (void *)rx_pkt, false, rx_pkt->pkt_tag);
1215 crystalhd_start_rx_dma_engine(hw);
1216 /* Program the Y descriptor */
1217 desc_addr.full_addr = rx_pkt->desc_mem.phy_addr;
1218 crystalhd_reg_wr(hw->adp, y_high_addr_reg, desc_addr.high_part);
1219 crystalhd_reg_wr(hw->adp, y_low_addr_reg, desc_addr.low_part | 0x01);
1221 if (rx_pkt->uv_phy_addr) {
1222 /* Program the UV descriptor */
1223 desc_addr.full_addr = rx_pkt->uv_phy_addr;
1224 crystalhd_reg_wr(hw->adp, uv_high_addr_reg, desc_addr.high_part);
1225 crystalhd_reg_wr(hw->adp, uv_low_addr_reg, desc_addr.low_part | 0x01);
1228 return BC_STS_SUCCESS;
1231 static enum BC_STATUS crystalhd_hw_post_cap_buff(struct crystalhd_hw *hw,
1232 struct crystalhd_rx_dma_pkt *rx_pkt)
1234 enum BC_STATUS sts = crystalhd_hw_prog_rxdma(hw, rx_pkt);
1236 if (sts == BC_STS_BUSY)
1237 crystalhd_dioq_add(hw->rx_freeq, (void *)rx_pkt,
1238 false, rx_pkt->pkt_tag);
1240 return sts;
1243 static void crystalhd_get_dnsz(struct crystalhd_hw *hw, uint32_t list_index,
1244 uint32_t *y_dw_dnsz, uint32_t *uv_dw_dnsz)
1246 uint32_t y_dn_sz_reg, uv_dn_sz_reg;
1248 if (!list_index) {
1249 y_dn_sz_reg = MISC1_Y_RX_LIST0_CUR_BYTE_CNT;
1250 uv_dn_sz_reg = MISC1_UV_RX_LIST0_CUR_BYTE_CNT;
1251 } else {
1252 y_dn_sz_reg = MISC1_Y_RX_LIST1_CUR_BYTE_CNT;
1253 uv_dn_sz_reg = MISC1_UV_RX_LIST1_CUR_BYTE_CNT;
1256 *y_dw_dnsz = crystalhd_reg_rd(hw->adp, y_dn_sz_reg);
1257 *uv_dw_dnsz = crystalhd_reg_rd(hw->adp, uv_dn_sz_reg);
1261 * This function should be called only after making sure that the two DMA
1262 * lists are free. This function does not check if DMA's are active, before
1263 * turning off the DMA.
1265 static void crystalhd_hw_finalize_pause(struct crystalhd_hw *hw)
1267 uint32_t dma_cntrl, aspm;
1269 hw->stop_pending = 0;
1271 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS);
1272 if (dma_cntrl & DMA_START_BIT) {
1273 dma_cntrl &= ~DMA_START_BIT;
1274 crystalhd_reg_wr(hw->adp, MISC1_Y_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1277 dma_cntrl = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS);
1278 if (dma_cntrl & DMA_START_BIT) {
1279 dma_cntrl &= ~DMA_START_BIT;
1280 crystalhd_reg_wr(hw->adp, MISC1_UV_RX_SW_DESC_LIST_CTRL_STS, dma_cntrl);
1282 hw->rx_list_post_index = 0;
1284 aspm = crystalhd_reg_rd(hw->adp, PCIE_DLL_DATA_LINK_CONTROL);
1285 aspm |= ASPM_L1_ENABLE;
1286 /* NAREN BCMLOG(BCMLOG_INFO, "aspm on\n"); */
1287 crystalhd_reg_wr(hw->adp, PCIE_DLL_DATA_LINK_CONTROL, aspm);
1290 static enum BC_STATUS crystalhd_rx_pkt_done(struct crystalhd_hw *hw, uint32_t list_index,
1291 enum BC_STATUS comp_sts)
1293 struct crystalhd_rx_dma_pkt *rx_pkt = NULL;
1294 uint32_t y_dw_dnsz, uv_dw_dnsz;
1295 enum BC_STATUS sts = BC_STS_SUCCESS;
1297 if (!hw || list_index >= DMA_ENGINE_CNT) {
1298 BCMLOG_ERR("Invalid Arguments\n");
1299 return BC_STS_INV_ARG;
1302 rx_pkt = crystalhd_dioq_find_and_fetch(hw->rx_actq,
1303 hw->rx_pkt_tag_seed + list_index);
1304 if (!rx_pkt) {
1305 BCMLOG_ERR("Act-Q:PostIx:%x L0Sts:%x L1Sts:%x current L:%x tag:%x comp:%x\n",
1306 hw->rx_list_post_index, hw->rx_list_sts[0],
1307 hw->rx_list_sts[1], list_index,
1308 hw->rx_pkt_tag_seed + list_index, comp_sts);
1309 return BC_STS_INV_ARG;
1312 if (comp_sts == BC_STS_SUCCESS) {
1313 crystalhd_get_dnsz(hw, list_index, &y_dw_dnsz, &uv_dw_dnsz);
1314 rx_pkt->dio_req->uinfo.y_done_sz = y_dw_dnsz;
1315 rx_pkt->flags = COMP_FLAG_DATA_VALID;
1316 if (rx_pkt->uv_phy_addr)
1317 rx_pkt->dio_req->uinfo.uv_done_sz = uv_dw_dnsz;
1318 crystalhd_dioq_add(hw->rx_rdyq, rx_pkt, true,
1319 hw->rx_pkt_tag_seed + list_index);
1320 return sts;
1323 /* Check if we can post this DIO again. */
1324 return crystalhd_hw_post_cap_buff(hw, rx_pkt);
1327 static bool crystalhd_rx_list0_handler(struct crystalhd_hw *hw, uint32_t int_sts,
1328 uint32_t y_err_sts, uint32_t uv_err_sts)
1330 uint32_t tmp;
1331 enum list_sts tmp_lsts;
1333 if (!(y_err_sts & GET_Y0_ERR_MSK) && !(uv_err_sts & GET_UV0_ERR_MSK))
1334 return false;
1336 tmp_lsts = hw->rx_list_sts[0];
1338 /* Y0 - DMA */
1339 tmp = y_err_sts & GET_Y0_ERR_MSK;
1340 if (int_sts & INTR_INTR_STATUS_L0_Y_RX_DMA_DONE_INTR_MASK)
1341 hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
1343 if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK) {
1344 hw->rx_list_sts[0] &= ~rx_waiting_y_intr;
1345 tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK;
1348 if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK) {
1349 hw->rx_list_sts[0] &= ~rx_y_mask;
1350 hw->rx_list_sts[0] |= rx_y_error;
1351 tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK;
1354 if (tmp) {
1355 hw->rx_list_sts[0] &= ~rx_y_mask;
1356 hw->rx_list_sts[0] |= rx_y_error;
1357 hw->rx_list_post_index = 0;
1360 /* UV0 - DMA */
1361 tmp = uv_err_sts & GET_UV0_ERR_MSK;
1362 if (int_sts & INTR_INTR_STATUS_L0_UV_RX_DMA_DONE_INTR_MASK)
1363 hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
1365 if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK) {
1366 hw->rx_list_sts[0] &= ~rx_waiting_uv_intr;
1367 tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L0_UNDERRUN_ERROR_MASK;
1370 if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK) {
1371 hw->rx_list_sts[0] &= ~rx_uv_mask;
1372 hw->rx_list_sts[0] |= rx_uv_error;
1373 tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L0_FIFO_FULL_ERRORS_MASK;
1376 if (tmp) {
1377 hw->rx_list_sts[0] &= ~rx_uv_mask;
1378 hw->rx_list_sts[0] |= rx_uv_error;
1379 hw->rx_list_post_index = 0;
1382 if (y_err_sts & GET_Y0_ERR_MSK) {
1383 tmp = y_err_sts & GET_Y0_ERR_MSK;
1384 crystalhd_reg_wr(hw->adp, MISC1_Y_RX_ERROR_STATUS, tmp);
1387 if (uv_err_sts & GET_UV0_ERR_MSK) {
1388 tmp = uv_err_sts & GET_UV0_ERR_MSK;
1389 crystalhd_reg_wr(hw->adp, MISC1_UV_RX_ERROR_STATUS, tmp);
1392 return (tmp_lsts != hw->rx_list_sts[0]);
1395 static bool crystalhd_rx_list1_handler(struct crystalhd_hw *hw, uint32_t int_sts,
1396 uint32_t y_err_sts, uint32_t uv_err_sts)
1398 uint32_t tmp;
1399 enum list_sts tmp_lsts;
1401 if (!(y_err_sts & GET_Y1_ERR_MSK) && !(uv_err_sts & GET_UV1_ERR_MSK))
1402 return false;
1404 tmp_lsts = hw->rx_list_sts[1];
1406 /* Y1 - DMA */
1407 tmp = y_err_sts & GET_Y1_ERR_MSK;
1408 if (int_sts & INTR_INTR_STATUS_L1_Y_RX_DMA_DONE_INTR_MASK)
1409 hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
1411 if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK) {
1412 hw->rx_list_sts[1] &= ~rx_waiting_y_intr;
1413 tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK;
1416 if (y_err_sts & MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK) {
1417 /* Add retry-support..*/
1418 hw->rx_list_sts[1] &= ~rx_y_mask;
1419 hw->rx_list_sts[1] |= rx_y_error;
1420 tmp &= ~MISC1_Y_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK;
1423 if (tmp) {
1424 hw->rx_list_sts[1] &= ~rx_y_mask;
1425 hw->rx_list_sts[1] |= rx_y_error;
1426 hw->rx_list_post_index = 0;
1429 /* UV1 - DMA */
1430 tmp = uv_err_sts & GET_UV1_ERR_MSK;
1431 if (int_sts & INTR_INTR_STATUS_L1_UV_RX_DMA_DONE_INTR_MASK)
1432 hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
1434 if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK) {
1435 hw->rx_list_sts[1] &= ~rx_waiting_uv_intr;
1436 tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L1_UNDERRUN_ERROR_MASK;
1439 if (uv_err_sts & MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK) {
1440 /* Add retry-support*/
1441 hw->rx_list_sts[1] &= ~rx_uv_mask;
1442 hw->rx_list_sts[1] |= rx_uv_error;
1443 tmp &= ~MISC1_UV_RX_ERROR_STATUS_RX_L1_FIFO_FULL_ERRORS_MASK;
1446 if (tmp) {
1447 hw->rx_list_sts[1] &= ~rx_uv_mask;
1448 hw->rx_list_sts[1] |= rx_uv_error;
1449 hw->rx_list_post_index = 0;
1452 if (y_err_sts & GET_Y1_ERR_MSK) {
1453 tmp = y_err_sts & GET_Y1_ERR_MSK;
1454 crystalhd_reg_wr(hw->adp, MISC1_Y_RX_ERROR_STATUS, tmp);
1457 if (uv_err_sts & GET_UV1_ERR_MSK) {
1458 tmp = uv_err_sts & GET_UV1_ERR_MSK;
1459 crystalhd_reg_wr(hw->adp, MISC1_UV_RX_ERROR_STATUS, tmp);
1462 return (tmp_lsts != hw->rx_list_sts[1]);
1466 static void crystalhd_rx_isr(struct crystalhd_hw *hw, uint32_t intr_sts)
1468 unsigned long flags;
1469 uint32_t i, list_avail = 0;
1470 enum BC_STATUS comp_sts = BC_STS_NO_DATA;
1471 uint32_t y_err_sts, uv_err_sts, y_dn_sz = 0, uv_dn_sz = 0;
1472 bool ret = 0;
1474 if (!hw) {
1475 BCMLOG_ERR("Invalid Arguments\n");
1476 return;
1479 if (!(intr_sts & GET_RX_INTR_MASK))
1480 return;
1482 y_err_sts = crystalhd_reg_rd(hw->adp, MISC1_Y_RX_ERROR_STATUS);
1483 uv_err_sts = crystalhd_reg_rd(hw->adp, MISC1_UV_RX_ERROR_STATUS);
1485 for (i = 0; i < DMA_ENGINE_CNT; i++) {
1486 /* Update States..*/
1487 spin_lock_irqsave(&hw->rx_lock, flags);
1488 if (i == 0)
1489 ret = crystalhd_rx_list0_handler(hw, intr_sts, y_err_sts, uv_err_sts);
1490 else
1491 ret = crystalhd_rx_list1_handler(hw, intr_sts, y_err_sts, uv_err_sts);
1492 if (ret) {
1493 switch (hw->rx_list_sts[i]) {
1494 case sts_free:
1495 comp_sts = BC_STS_SUCCESS;
1496 list_avail = 1;
1497 break;
1498 case rx_y_error:
1499 case rx_uv_error:
1500 case rx_sts_error:
1501 /* We got error on both or Y or uv. */
1502 hw->stats.rx_errors++;
1503 crystalhd_get_dnsz(hw, i, &y_dn_sz, &uv_dn_sz);
1504 /* FIXME: jarod: this is where my mini pci-e card is tripping up */
1505 BCMLOG(BCMLOG_DBG, "list_index:%x rx[%d] Y:%x "
1506 "UV:%x Int:%x YDnSz:%x UVDnSz:%x\n",
1507 i, hw->stats.rx_errors, y_err_sts,
1508 uv_err_sts, intr_sts, y_dn_sz, uv_dn_sz);
1509 hw->rx_list_sts[i] = sts_free;
1510 comp_sts = BC_STS_ERROR;
1511 break;
1512 default:
1513 /* Wait for completion..*/
1514 comp_sts = BC_STS_NO_DATA;
1515 break;
1518 spin_unlock_irqrestore(&hw->rx_lock, flags);
1520 /* handle completion...*/
1521 if (comp_sts != BC_STS_NO_DATA) {
1522 crystalhd_rx_pkt_done(hw, i, comp_sts);
1523 comp_sts = BC_STS_NO_DATA;
1527 if (list_avail) {
1528 if (hw->stop_pending) {
1529 if ((hw->rx_list_sts[0] == sts_free) &&
1530 (hw->rx_list_sts[1] == sts_free))
1531 crystalhd_hw_finalize_pause(hw);
1532 } else {
1533 crystalhd_hw_start_capture(hw);
1538 static enum BC_STATUS crystalhd_fw_cmd_post_proc(struct crystalhd_hw *hw,
1539 struct BC_FW_CMD *fw_cmd)
1541 enum BC_STATUS sts = BC_STS_SUCCESS;
1542 struct dec_rsp_channel_start_video *st_rsp = NULL;
1544 switch (fw_cmd->cmd[0]) {
1545 case eCMD_C011_DEC_CHAN_START_VIDEO:
1546 st_rsp = (struct dec_rsp_channel_start_video *)fw_cmd->rsp;
1547 hw->pib_del_Q_addr = st_rsp->picInfoDeliveryQ;
1548 hw->pib_rel_Q_addr = st_rsp->picInfoReleaseQ;
1549 BCMLOG(BCMLOG_DBG, "DelQAddr:%x RelQAddr:%x\n",
1550 hw->pib_del_Q_addr, hw->pib_rel_Q_addr);
1551 break;
1552 case eCMD_C011_INIT:
1553 if (!(crystalhd_load_firmware_config(hw->adp))) {
1554 BCMLOG_ERR("Invalid Params.\n");
1555 sts = BC_STS_FW_AUTH_FAILED;
1557 break;
1558 default:
1559 break;
1561 return sts;
1564 static enum BC_STATUS crystalhd_put_ddr2sleep(struct crystalhd_hw *hw)
1566 uint32_t reg;
1567 union link_misc_perst_decoder_ctrl rst_cntrl_reg;
1569 /* Pulse reset pin of 7412 (MISC_PERST_DECODER_CTRL) */
1570 rst_cntrl_reg.whole_reg = crystalhd_reg_rd(hw->adp, MISC_PERST_DECODER_CTRL);
1572 rst_cntrl_reg.bcm_7412_rst = 1;
1573 crystalhd_reg_wr(hw->adp, MISC_PERST_DECODER_CTRL, rst_cntrl_reg.whole_reg);
1574 msleep_interruptible(50);
1576 rst_cntrl_reg.bcm_7412_rst = 0;
1577 crystalhd_reg_wr(hw->adp, MISC_PERST_DECODER_CTRL, rst_cntrl_reg.whole_reg);
1579 /* Close all banks, put DDR in idle */
1580 bc_dec_reg_wr(hw->adp, SDRAM_PRECHARGE, 0);
1582 /* Set bit 25 (drop CKE pin of DDR) */
1583 reg = bc_dec_reg_rd(hw->adp, SDRAM_PARAM);
1584 reg |= 0x02000000;
1585 bc_dec_reg_wr(hw->adp, SDRAM_PARAM, reg);
1587 /* Reset the audio block */
1588 bc_dec_reg_wr(hw->adp, AUD_DSP_MISC_SOFT_RESET, 0x1);
1590 /* Power down Raptor PLL */
1591 reg = bc_dec_reg_rd(hw->adp, DecHt_PllCCtl);
1592 reg |= 0x00008000;
1593 bc_dec_reg_wr(hw->adp, DecHt_PllCCtl, reg);
1595 /* Power down all Audio PLL */
1596 bc_dec_reg_wr(hw->adp, AIO_MISC_PLL_RESET, 0x1);
1598 /* Power down video clock (75MHz) */
1599 reg = bc_dec_reg_rd(hw->adp, DecHt_PllECtl);
1600 reg |= 0x00008000;
1601 bc_dec_reg_wr(hw->adp, DecHt_PllECtl, reg);
1603 /* Power down video clock (75MHz) */
1604 reg = bc_dec_reg_rd(hw->adp, DecHt_PllDCtl);
1605 reg |= 0x00008000;
1606 bc_dec_reg_wr(hw->adp, DecHt_PllDCtl, reg);
1608 /* Power down core clock (200MHz) */
1609 reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
1610 reg |= 0x00008000;
1611 bc_dec_reg_wr(hw->adp, DecHt_PllACtl, reg);
1613 /* Power down core clock (200MHz) */
1614 reg = bc_dec_reg_rd(hw->adp, DecHt_PllBCtl);
1615 reg |= 0x00008000;
1616 bc_dec_reg_wr(hw->adp, DecHt_PllBCtl, reg);
1618 return BC_STS_SUCCESS;
1621 /************************************************
1623 *************************************************/
1625 enum BC_STATUS crystalhd_download_fw(struct crystalhd_adp *adp, void *buffer, uint32_t sz)
1627 uint32_t reg_data, cnt, *temp_buff;
1628 uint32_t fw_sig_len = 36;
1629 uint32_t dram_offset = BC_FWIMG_ST_ADDR, sig_reg;
1631 BCMLOG_ENTER;
1633 if (!adp || !buffer || !sz) {
1634 BCMLOG_ERR("Invalid Params.\n");
1635 return BC_STS_INV_ARG;
1638 reg_data = crystalhd_reg_rd(adp, OTP_CMD);
1639 if (!(reg_data & 0x02)) {
1640 BCMLOG_ERR("Invalid hw config.. otp not programmed\n");
1641 return BC_STS_ERROR;
1644 reg_data = 0;
1645 crystalhd_reg_wr(adp, DCI_CMD, 0);
1646 reg_data |= BC_BIT(0);
1647 crystalhd_reg_wr(adp, DCI_CMD, reg_data);
1649 reg_data = 0;
1650 cnt = 1000;
1651 msleep_interruptible(10);
1653 while (reg_data != BC_BIT(4)) {
1654 reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
1655 reg_data &= BC_BIT(4);
1656 if (--cnt == 0) {
1657 BCMLOG_ERR("Firmware Download RDY Timeout.\n");
1658 return BC_STS_TIMEOUT;
1662 msleep_interruptible(10);
1663 /* Load the FW to the FW_ADDR field in the DCI_FIRMWARE_ADDR */
1664 crystalhd_reg_wr(adp, DCI_FIRMWARE_ADDR, dram_offset);
1665 temp_buff = (uint32_t *)buffer;
1666 for (cnt = 0; cnt < (sz - fw_sig_len); cnt += 4) {
1667 crystalhd_reg_wr(adp, DCI_DRAM_BASE_ADDR, (dram_offset >> 19));
1668 crystalhd_reg_wr(adp, DCI_FIRMWARE_DATA, *temp_buff);
1669 dram_offset += 4;
1670 temp_buff++;
1672 msleep_interruptible(10);
1674 temp_buff++;
1676 sig_reg = (uint32_t)DCI_SIGNATURE_DATA_7;
1677 for (cnt = 0; cnt < 8; cnt++) {
1678 uint32_t swapped_data = *temp_buff;
1679 swapped_data = bswap_32_1(swapped_data);
1680 crystalhd_reg_wr(adp, sig_reg, swapped_data);
1681 sig_reg -= 4;
1682 temp_buff++;
1684 msleep_interruptible(10);
1686 reg_data = 0;
1687 reg_data |= BC_BIT(1);
1688 crystalhd_reg_wr(adp, DCI_CMD, reg_data);
1689 msleep_interruptible(10);
1691 reg_data = 0;
1692 reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
1694 if ((reg_data & BC_BIT(9)) == BC_BIT(9)) {
1695 cnt = 1000;
1696 while ((reg_data & BC_BIT(0)) != BC_BIT(0)) {
1697 reg_data = crystalhd_reg_rd(adp, DCI_STATUS);
1698 reg_data &= BC_BIT(0);
1699 if (!(--cnt))
1700 break;
1701 msleep_interruptible(10);
1703 reg_data = 0;
1704 reg_data = crystalhd_reg_rd(adp, DCI_CMD);
1705 reg_data |= BC_BIT(4);
1706 crystalhd_reg_wr(adp, DCI_CMD, reg_data);
1708 } else {
1709 BCMLOG_ERR("F/w Signature mismatch\n");
1710 return BC_STS_FW_AUTH_FAILED;
1713 BCMLOG(BCMLOG_INFO, "Firmware Downloaded Successfully\n");
1714 return BC_STS_SUCCESS;
1717 enum BC_STATUS crystalhd_do_fw_cmd(struct crystalhd_hw *hw,
1718 struct BC_FW_CMD *fw_cmd)
1720 uint32_t cnt = 0, cmd_res_addr;
1721 uint32_t *cmd_buff, *res_buff;
1722 wait_queue_head_t fw_cmd_event;
1723 int rc = 0;
1724 enum BC_STATUS sts;
1726 crystalhd_create_event(&fw_cmd_event);
1728 BCMLOG_ENTER;
1730 if (!hw || !fw_cmd) {
1731 BCMLOG_ERR("Invalid Arguments\n");
1732 return BC_STS_INV_ARG;
1735 cmd_buff = fw_cmd->cmd;
1736 res_buff = fw_cmd->rsp;
1738 if (!cmd_buff || !res_buff) {
1739 BCMLOG_ERR("Invalid Parameters for F/W Command\n");
1740 return BC_STS_INV_ARG;
1743 hw->pwr_lock++;
1745 hw->fwcmd_evt_sts = 0;
1746 hw->pfw_cmd_event = &fw_cmd_event;
1748 /*Write the command to the memory*/
1749 crystalhd_mem_wr(hw->adp, TS_Host2CpuSnd, FW_CMD_BUFF_SZ, cmd_buff);
1751 /*Memory Read for memory arbitrator flush*/
1752 crystalhd_mem_rd(hw->adp, TS_Host2CpuSnd, 1, &cnt);
1754 /* Write the command address to mailbox */
1755 bc_dec_reg_wr(hw->adp, Hst2CpuMbx1, TS_Host2CpuSnd);
1756 msleep_interruptible(50);
1758 crystalhd_wait_on_event(&fw_cmd_event, hw->fwcmd_evt_sts, 20000, rc, 0);
1760 if (!rc) {
1761 sts = BC_STS_SUCCESS;
1762 } else if (rc == -EBUSY) {
1763 BCMLOG_ERR("Firmware command T/O\n");
1764 sts = BC_STS_TIMEOUT;
1765 } else if (rc == -EINTR) {
1766 BCMLOG(BCMLOG_DBG, "FwCmd Wait Signal int.\n");
1767 sts = BC_STS_IO_USER_ABORT;
1768 } else {
1769 BCMLOG_ERR("FwCmd IO Error.\n");
1770 sts = BC_STS_IO_ERROR;
1773 if (sts != BC_STS_SUCCESS) {
1774 BCMLOG_ERR("FwCmd Failed.\n");
1775 hw->pwr_lock--;
1776 return sts;
1779 /*Get the Response Address*/
1780 cmd_res_addr = bc_dec_reg_rd(hw->adp, Cpu2HstMbx1);
1782 /*Read the Response*/
1783 crystalhd_mem_rd(hw->adp, cmd_res_addr, FW_CMD_BUFF_SZ, res_buff);
1785 hw->pwr_lock--;
1787 if (res_buff[2] != C011_RET_SUCCESS) {
1788 BCMLOG_ERR("res_buff[2] != C011_RET_SUCCESS\n");
1789 return BC_STS_FW_CMD_ERR;
1792 sts = crystalhd_fw_cmd_post_proc(hw, fw_cmd);
1793 if (sts != BC_STS_SUCCESS)
1794 BCMLOG_ERR("crystalhd_fw_cmd_post_proc Failed.\n");
1796 return sts;
1799 bool crystalhd_hw_interrupt(struct crystalhd_adp *adp, struct crystalhd_hw *hw)
1801 uint32_t intr_sts = 0;
1802 uint32_t deco_intr = 0;
1803 bool rc = 0;
1805 if (!adp || !hw->dev_started)
1806 return rc;
1808 hw->stats.num_interrupts++;
1809 hw->pwr_lock++;
1811 deco_intr = bc_dec_reg_rd(adp, Stream2Host_Intr_Sts);
1812 intr_sts = crystalhd_reg_rd(adp, INTR_INTR_STATUS);
1814 if (intr_sts) {
1815 /* let system know we processed interrupt..*/
1816 rc = 1;
1817 hw->stats.dev_interrupts++;
1820 if (deco_intr && (deco_intr != 0xdeaddead)) {
1822 if (deco_intr & 0x80000000) {
1823 /*Set the Event and the status flag*/
1824 if (hw->pfw_cmd_event) {
1825 hw->fwcmd_evt_sts = 1;
1826 crystalhd_set_event(hw->pfw_cmd_event);
1830 if (deco_intr & BC_BIT(1))
1831 crystalhd_hw_proc_pib(hw);
1833 bc_dec_reg_wr(adp, Stream2Host_Intr_Sts, deco_intr);
1834 /* FIXME: jarod: No udelay? might this be the real reason mini pci-e cards were stalling out? */
1835 bc_dec_reg_wr(adp, Stream2Host_Intr_Sts, 0);
1836 rc = 1;
1839 /* Rx interrupts */
1840 crystalhd_rx_isr(hw, intr_sts);
1842 /* Tx interrupts*/
1843 crystalhd_tx_isr(hw, intr_sts);
1845 /* Clear interrupts */
1846 if (rc) {
1847 if (intr_sts)
1848 crystalhd_reg_wr(adp, INTR_INTR_CLR_REG, intr_sts);
1850 crystalhd_reg_wr(adp, INTR_EOI_CTRL, 1);
1853 hw->pwr_lock--;
1855 return rc;
1858 enum BC_STATUS crystalhd_hw_open(struct crystalhd_hw *hw, struct crystalhd_adp *adp)
1860 if (!hw || !adp) {
1861 BCMLOG_ERR("Invalid Arguments\n");
1862 return BC_STS_INV_ARG;
1865 if (hw->dev_started)
1866 return BC_STS_SUCCESS;
1868 memset(hw, 0, sizeof(struct crystalhd_hw));
1870 hw->adp = adp;
1871 spin_lock_init(&hw->lock);
1872 spin_lock_init(&hw->rx_lock);
1873 /* FIXME: jarod: what are these magic numbers?!? */
1874 hw->tx_ioq_tag_seed = 0x70023070;
1875 hw->rx_pkt_tag_seed = 0x70029070;
1877 hw->stop_pending = 0;
1878 crystalhd_start_device(hw->adp);
1879 hw->dev_started = true;
1881 /* set initial core clock */
1882 hw->core_clock_mhz = CLOCK_PRESET;
1883 hw->prev_n = 0;
1884 hw->pwr_lock = 0;
1885 crystalhd_hw_set_core_clock(hw);
1887 return BC_STS_SUCCESS;
1890 enum BC_STATUS crystalhd_hw_close(struct crystalhd_hw *hw)
1892 if (!hw) {
1893 BCMLOG_ERR("Invalid Arguments\n");
1894 return BC_STS_INV_ARG;
1897 if (!hw->dev_started)
1898 return BC_STS_SUCCESS;
1900 /* Stop and DDR sleep will happen in here */
1901 crystalhd_hw_suspend(hw);
1902 hw->dev_started = false;
1904 return BC_STS_SUCCESS;
1907 enum BC_STATUS crystalhd_hw_setup_dma_rings(struct crystalhd_hw *hw)
1909 unsigned int i;
1910 void *mem;
1911 size_t mem_len;
1912 dma_addr_t phy_addr;
1913 enum BC_STATUS sts = BC_STS_SUCCESS;
1914 struct crystalhd_rx_dma_pkt *rpkt;
1916 if (!hw || !hw->adp) {
1917 BCMLOG_ERR("Invalid Arguments\n");
1918 return BC_STS_INV_ARG;
1921 sts = crystalhd_hw_create_ioqs(hw);
1922 if (sts != BC_STS_SUCCESS) {
1923 BCMLOG_ERR("Failed to create IOQs..\n");
1924 return sts;
1927 mem_len = BC_LINK_MAX_SGLS * sizeof(struct dma_descriptor);
1929 for (i = 0; i < BC_TX_LIST_CNT; i++) {
1930 mem = bc_kern_dma_alloc(hw->adp, mem_len, &phy_addr);
1931 if (mem) {
1932 memset(mem, 0, mem_len);
1933 } else {
1934 BCMLOG_ERR("Insufficient Memory For TX\n");
1935 crystalhd_hw_free_dma_rings(hw);
1936 return BC_STS_INSUFF_RES;
1938 /* rx_pkt_pool -- static memory allocation */
1939 hw->tx_pkt_pool[i].desc_mem.pdma_desc_start = mem;
1940 hw->tx_pkt_pool[i].desc_mem.phy_addr = phy_addr;
1941 hw->tx_pkt_pool[i].desc_mem.sz = BC_LINK_MAX_SGLS *
1942 sizeof(struct dma_descriptor);
1943 hw->tx_pkt_pool[i].list_tag = 0;
1945 /* Add TX dma requests to Free Queue..*/
1946 sts = crystalhd_dioq_add(hw->tx_freeq,
1947 &hw->tx_pkt_pool[i], false, 0);
1948 if (sts != BC_STS_SUCCESS) {
1949 crystalhd_hw_free_dma_rings(hw);
1950 return sts;
1954 for (i = 0; i < BC_RX_LIST_CNT; i++) {
1955 rpkt = kzalloc(sizeof(*rpkt), GFP_KERNEL);
1956 if (!rpkt) {
1957 BCMLOG_ERR("Insufficient Memory For RX\n");
1958 crystalhd_hw_free_dma_rings(hw);
1959 return BC_STS_INSUFF_RES;
1962 mem = bc_kern_dma_alloc(hw->adp, mem_len, &phy_addr);
1963 if (mem) {
1964 memset(mem, 0, mem_len);
1965 } else {
1966 BCMLOG_ERR("Insufficient Memory For RX\n");
1967 crystalhd_hw_free_dma_rings(hw);
1968 kfree(rpkt);
1969 return BC_STS_INSUFF_RES;
1971 rpkt->desc_mem.pdma_desc_start = mem;
1972 rpkt->desc_mem.phy_addr = phy_addr;
1973 rpkt->desc_mem.sz = BC_LINK_MAX_SGLS * sizeof(struct dma_descriptor);
1974 rpkt->pkt_tag = hw->rx_pkt_tag_seed + i;
1975 crystalhd_hw_free_rx_pkt(hw, rpkt);
1978 return BC_STS_SUCCESS;
1981 enum BC_STATUS crystalhd_hw_free_dma_rings(struct crystalhd_hw *hw)
1983 unsigned int i;
1984 struct crystalhd_rx_dma_pkt *rpkt = NULL;
1986 if (!hw || !hw->adp) {
1987 BCMLOG_ERR("Invalid Arguments\n");
1988 return BC_STS_INV_ARG;
1991 /* Delete all IOQs.. */
1992 crystalhd_hw_delete_ioqs(hw);
1994 for (i = 0; i < BC_TX_LIST_CNT; i++) {
1995 if (hw->tx_pkt_pool[i].desc_mem.pdma_desc_start) {
1996 bc_kern_dma_free(hw->adp,
1997 hw->tx_pkt_pool[i].desc_mem.sz,
1998 hw->tx_pkt_pool[i].desc_mem.pdma_desc_start,
1999 hw->tx_pkt_pool[i].desc_mem.phy_addr);
2001 hw->tx_pkt_pool[i].desc_mem.pdma_desc_start = NULL;
2005 BCMLOG(BCMLOG_DBG, "Releasing RX Pkt pool\n");
2006 do {
2007 rpkt = crystalhd_hw_alloc_rx_pkt(hw);
2008 if (!rpkt)
2009 break;
2010 bc_kern_dma_free(hw->adp, rpkt->desc_mem.sz,
2011 rpkt->desc_mem.pdma_desc_start,
2012 rpkt->desc_mem.phy_addr);
2013 kfree(rpkt);
2014 } while (rpkt);
2016 return BC_STS_SUCCESS;
2019 enum BC_STATUS crystalhd_hw_post_tx(struct crystalhd_hw *hw, struct crystalhd_dio_req *ioreq,
2020 hw_comp_callback call_back,
2021 wait_queue_head_t *cb_event, uint32_t *list_id,
2022 uint8_t data_flags)
2024 struct tx_dma_pkt *tx_dma_packet = NULL;
2025 uint32_t first_desc_u_addr, first_desc_l_addr;
2026 uint32_t low_addr, high_addr;
2027 union addr_64 desc_addr;
2028 enum BC_STATUS sts, add_sts;
2029 uint32_t dummy_index = 0;
2030 unsigned long flags;
2031 bool rc;
2033 if (!hw || !ioreq || !call_back || !cb_event || !list_id) {
2034 BCMLOG_ERR("Invalid Arguments\n");
2035 return BC_STS_INV_ARG;
2039 * Since we hit code in busy condition very frequently,
2040 * we will check the code in status first before
2041 * checking the availability of free elem.
2043 * This will avoid the Q fetch/add in normal condition.
2045 rc = crystalhd_code_in_full(hw->adp, ioreq->uinfo.xfr_len,
2046 false, data_flags);
2047 if (rc) {
2048 hw->stats.cin_busy++;
2049 return BC_STS_BUSY;
2052 /* Get a list from TxFreeQ */
2053 tx_dma_packet = (struct tx_dma_pkt *)crystalhd_dioq_fetch(hw->tx_freeq);
2054 if (!tx_dma_packet) {
2055 BCMLOG_ERR("No empty elements..\n");
2056 return BC_STS_ERR_USAGE;
2059 sts = crystalhd_xlat_sgl_to_dma_desc(ioreq,
2060 &tx_dma_packet->desc_mem,
2061 &dummy_index);
2062 if (sts != BC_STS_SUCCESS) {
2063 add_sts = crystalhd_dioq_add(hw->tx_freeq, tx_dma_packet,
2064 false, 0);
2065 if (add_sts != BC_STS_SUCCESS)
2066 BCMLOG_ERR("double fault..\n");
2068 return sts;
2071 hw->pwr_lock++;
2073 desc_addr.full_addr = tx_dma_packet->desc_mem.phy_addr;
2074 low_addr = desc_addr.low_part;
2075 high_addr = desc_addr.high_part;
2077 tx_dma_packet->call_back = call_back;
2078 tx_dma_packet->cb_event = cb_event;
2079 tx_dma_packet->dio_req = ioreq;
2081 spin_lock_irqsave(&hw->lock, flags);
2083 if (hw->tx_list_post_index == 0) {
2084 first_desc_u_addr = MISC1_TX_FIRST_DESC_U_ADDR_LIST0;
2085 first_desc_l_addr = MISC1_TX_FIRST_DESC_L_ADDR_LIST0;
2086 } else {
2087 first_desc_u_addr = MISC1_TX_FIRST_DESC_U_ADDR_LIST1;
2088 first_desc_l_addr = MISC1_TX_FIRST_DESC_L_ADDR_LIST1;
2091 *list_id = tx_dma_packet->list_tag = hw->tx_ioq_tag_seed +
2092 hw->tx_list_post_index;
2094 hw->tx_list_post_index = (hw->tx_list_post_index + 1) % DMA_ENGINE_CNT;
2096 spin_unlock_irqrestore(&hw->lock, flags);
2099 /* Insert in Active Q..*/
2100 crystalhd_dioq_add(hw->tx_actq, tx_dma_packet, false,
2101 tx_dma_packet->list_tag);
2104 * Interrupt will come as soon as you write
2105 * the valid bit. So be ready for that. All
2106 * the initialization should happen before that.
2108 crystalhd_start_tx_dma_engine(hw);
2109 crystalhd_reg_wr(hw->adp, first_desc_u_addr, desc_addr.high_part);
2111 crystalhd_reg_wr(hw->adp, first_desc_l_addr, desc_addr.low_part | 0x01);
2112 /* Be sure we set the valid bit ^^^^ */
2114 return BC_STS_SUCCESS;
2118 * This is a force cancel and we are racing with ISR.
2120 * Will try to remove the req from ActQ before ISR gets it.
2121 * If ISR gets it first then the completion happens in the
2122 * normal path and we will return _STS_NO_DATA from here.
2124 * FIX_ME: Not Tested the actual condition..
2126 enum BC_STATUS crystalhd_hw_cancel_tx(struct crystalhd_hw *hw, uint32_t list_id)
2128 if (!hw || !list_id) {
2129 BCMLOG_ERR("Invalid Arguments\n");
2130 return BC_STS_INV_ARG;
2133 crystalhd_stop_tx_dma_engine(hw);
2134 crystalhd_hw_tx_req_complete(hw, list_id, BC_STS_IO_USER_ABORT);
2136 return BC_STS_SUCCESS;
2139 enum BC_STATUS crystalhd_hw_add_cap_buffer(struct crystalhd_hw *hw,
2140 struct crystalhd_dio_req *ioreq, bool en_post)
2142 struct crystalhd_rx_dma_pkt *rpkt;
2143 uint32_t tag, uv_desc_ix = 0;
2144 enum BC_STATUS sts;
2146 if (!hw || !ioreq) {
2147 BCMLOG_ERR("Invalid Arguments\n");
2148 return BC_STS_INV_ARG;
2151 rpkt = crystalhd_hw_alloc_rx_pkt(hw);
2152 if (!rpkt) {
2153 BCMLOG_ERR("Insufficient resources\n");
2154 return BC_STS_INSUFF_RES;
2157 rpkt->dio_req = ioreq;
2158 tag = rpkt->pkt_tag;
2160 sts = crystalhd_xlat_sgl_to_dma_desc(ioreq, &rpkt->desc_mem, &uv_desc_ix);
2161 if (sts != BC_STS_SUCCESS)
2162 return sts;
2164 rpkt->uv_phy_addr = 0;
2166 /* Store the address of UV in the rx packet for post*/
2167 if (uv_desc_ix)
2168 rpkt->uv_phy_addr = rpkt->desc_mem.phy_addr +
2169 (sizeof(struct dma_descriptor) * (uv_desc_ix + 1));
2171 if (en_post)
2172 sts = crystalhd_hw_post_cap_buff(hw, rpkt);
2173 else
2174 sts = crystalhd_dioq_add(hw->rx_freeq, rpkt, false, tag);
2176 return sts;
2179 enum BC_STATUS crystalhd_hw_get_cap_buffer(struct crystalhd_hw *hw,
2180 struct BC_PIC_INFO_BLOCK *pib,
2181 struct crystalhd_dio_req **ioreq)
2183 struct crystalhd_rx_dma_pkt *rpkt;
2184 uint32_t timeout = BC_PROC_OUTPUT_TIMEOUT / 1000;
2185 uint32_t sig_pending = 0;
2188 if (!hw || !ioreq || !pib) {
2189 BCMLOG_ERR("Invalid Arguments\n");
2190 return BC_STS_INV_ARG;
2193 rpkt = crystalhd_dioq_fetch_wait(hw->rx_rdyq, timeout, &sig_pending);
2194 if (!rpkt) {
2195 if (sig_pending) {
2196 BCMLOG(BCMLOG_INFO, "wait on frame time out %d\n", sig_pending);
2197 return BC_STS_IO_USER_ABORT;
2198 } else {
2199 return BC_STS_TIMEOUT;
2203 rpkt->dio_req->uinfo.comp_flags = rpkt->flags;
2205 if (rpkt->flags & COMP_FLAG_PIB_VALID)
2206 memcpy(pib, &rpkt->pib, sizeof(*pib));
2208 *ioreq = rpkt->dio_req;
2210 crystalhd_hw_free_rx_pkt(hw, rpkt);
2212 return BC_STS_SUCCESS;
2215 enum BC_STATUS crystalhd_hw_start_capture(struct crystalhd_hw *hw)
2217 struct crystalhd_rx_dma_pkt *rx_pkt;
2218 enum BC_STATUS sts;
2219 uint32_t i;
2221 if (!hw) {
2222 BCMLOG_ERR("Invalid Arguments\n");
2223 return BC_STS_INV_ARG;
2226 /* This is start of capture.. Post to both the lists.. */
2227 for (i = 0; i < DMA_ENGINE_CNT; i++) {
2228 rx_pkt = crystalhd_dioq_fetch(hw->rx_freeq);
2229 if (!rx_pkt)
2230 return BC_STS_NO_DATA;
2231 sts = crystalhd_hw_post_cap_buff(hw, rx_pkt);
2232 if (BC_STS_SUCCESS != sts)
2233 break;
2237 return BC_STS_SUCCESS;
2240 enum BC_STATUS crystalhd_hw_stop_capture(struct crystalhd_hw *hw)
2242 void *temp = NULL;
2244 if (!hw) {
2245 BCMLOG_ERR("Invalid Arguments\n");
2246 return BC_STS_INV_ARG;
2249 crystalhd_stop_rx_dma_engine(hw);
2251 do {
2252 temp = crystalhd_dioq_fetch(hw->rx_freeq);
2253 if (temp)
2254 crystalhd_rx_pkt_rel_call_back(hw, temp);
2255 } while (temp);
2257 return BC_STS_SUCCESS;
2260 enum BC_STATUS crystalhd_hw_pause(struct crystalhd_hw *hw)
2262 hw->stats.pause_cnt++;
2263 hw->stop_pending = 1;
2265 if ((hw->rx_list_sts[0] == sts_free) &&
2266 (hw->rx_list_sts[1] == sts_free))
2267 crystalhd_hw_finalize_pause(hw);
2269 return BC_STS_SUCCESS;
2272 enum BC_STATUS crystalhd_hw_unpause(struct crystalhd_hw *hw)
2274 enum BC_STATUS sts;
2275 uint32_t aspm;
2277 hw->stop_pending = 0;
2279 aspm = crystalhd_reg_rd(hw->adp, PCIE_DLL_DATA_LINK_CONTROL);
2280 aspm &= ~ASPM_L1_ENABLE;
2281 /* NAREN BCMLOG(BCMLOG_INFO, "aspm off\n"); */
2282 crystalhd_reg_wr(hw->adp, PCIE_DLL_DATA_LINK_CONTROL, aspm);
2284 sts = crystalhd_hw_start_capture(hw);
2285 return sts;
2288 enum BC_STATUS crystalhd_hw_suspend(struct crystalhd_hw *hw)
2290 enum BC_STATUS sts;
2292 if (!hw) {
2293 BCMLOG_ERR("Invalid Arguments\n");
2294 return BC_STS_INV_ARG;
2297 sts = crystalhd_put_ddr2sleep(hw);
2298 if (sts != BC_STS_SUCCESS) {
2299 BCMLOG_ERR("Failed to Put DDR To Sleep!!\n");
2300 return BC_STS_ERROR;
2303 if (!crystalhd_stop_device(hw->adp)) {
2304 BCMLOG_ERR("Failed to Stop Device!!\n");
2305 return BC_STS_ERROR;
2308 return BC_STS_SUCCESS;
2311 void crystalhd_hw_stats(struct crystalhd_hw *hw, struct crystalhd_hw_stats *stats)
2313 if (!hw) {
2314 BCMLOG_ERR("Invalid Arguments\n");
2315 return;
2318 /* if called w/NULL stats, its a req to zero out the stats */
2319 if (!stats) {
2320 memset(&hw->stats, 0, sizeof(hw->stats));
2321 return;
2324 hw->stats.freeq_count = crystalhd_dioq_count(hw->rx_freeq);
2325 hw->stats.rdyq_count = crystalhd_dioq_count(hw->rx_rdyq);
2326 memcpy(stats, &hw->stats, sizeof(*stats));
2329 enum BC_STATUS crystalhd_hw_set_core_clock(struct crystalhd_hw *hw)
2331 uint32_t reg, n, i;
2332 uint32_t vco_mg, refresh_reg;
2334 if (!hw) {
2335 BCMLOG_ERR("Invalid Arguments\n");
2336 return BC_STS_INV_ARG;
2339 /* FIXME: jarod: wha? */
2340 /*n = (hw->core_clock_mhz * 3) / 20 + 1; */
2341 n = hw->core_clock_mhz/5;
2343 if (n == hw->prev_n)
2344 return BC_STS_CLK_NOCHG;
2346 if (hw->pwr_lock > 0) {
2347 /* BCMLOG(BCMLOG_INFO,"pwr_lock is %u\n", hw->pwr_lock) */
2348 return BC_STS_CLK_NOCHG;
2351 i = n * 27;
2352 if (i < 560)
2353 vco_mg = 0;
2354 else if (i < 900)
2355 vco_mg = 1;
2356 else if (i < 1030)
2357 vco_mg = 2;
2358 else
2359 vco_mg = 3;
2361 reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
2363 reg &= 0xFFFFCFC0;
2364 reg |= n;
2365 reg |= vco_mg << 12;
2367 BCMLOG(BCMLOG_INFO, "clock is moving to %d with n %d with vco_mg %d\n",
2368 hw->core_clock_mhz, n, vco_mg);
2370 /* Change the DRAM refresh rate to accommodate the new frequency */
2371 /* refresh reg = ((refresh_rate * clock_rate)/16) - 1; rounding up*/
2372 refresh_reg = (7 * hw->core_clock_mhz / 16);
2373 bc_dec_reg_wr(hw->adp, SDRAM_REF_PARAM, ((1 << 12) | refresh_reg));
2375 bc_dec_reg_wr(hw->adp, DecHt_PllACtl, reg);
2377 i = 0;
2379 for (i = 0; i < 10; i++) {
2380 reg = bc_dec_reg_rd(hw->adp, DecHt_PllACtl);
2382 if (reg & 0x00020000) {
2383 hw->prev_n = n;
2384 /* FIXME: jarod: outputting a random "C" is... confusing... */
2385 BCMLOG(BCMLOG_INFO, "C");
2386 return BC_STS_SUCCESS;
2387 } else {
2388 msleep_interruptible(10);
2391 BCMLOG(BCMLOG_INFO, "clk change failed\n");
2392 return BC_STS_CLK_NOCHG;