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Stephan Linze1fd4be2012-02-25 00:48:31 +00001/*
2 * Xilinx xps_ll_temac ethernet driver for u-boot
3 *
4 * SDMA sub-controller
5 *
6 * Copyright (C) 2011 - 2012 Stephan Linz <linz@li-pro.net>
7 * Copyright (C) 2008 - 2011 Michal Simek <monstr@monstr.eu>
8 * Copyright (C) 2008 - 2011 PetaLogix
9 *
10 * Based on Yoshio Kashiwagi kashiwagi@co-nss.co.jp driver
11 * Copyright (C) 2008 Nissin Systems Co.,Ltd.
12 * March 2008 created
13 *
14 * CREDITS: tsec driver
15 *
Wolfgang Denkd79de1d2013-07-08 09:37:19 +020016 * SPDX-License-Identifier: GPL-2.0+
Stephan Linze1fd4be2012-02-25 00:48:31 +000017 *
18 * [0]: http://www.xilinx.com/support/documentation
19 *
20 * [M]: [0]/ip_documentation/mpmc.pdf
21 * [S]: [0]/ip_documentation/xps_ll_temac.pdf
22 * [A]: [0]/application_notes/xapp1041.pdf
23 */
24
25#include <config.h>
26#include <common.h>
27#include <net.h>
28
29#include <asm/types.h>
30#include <asm/io.h>
31
32#include "xilinx_ll_temac.h"
33#include "xilinx_ll_temac_sdma.h"
34
35#define TX_BUF_CNT 2
36
37static unsigned int rx_idx; /* index of the current RX buffer */
38static unsigned int tx_idx; /* index of the current TX buffer */
39
40struct rtx_cdmac_bd {
41 struct cdmac_bd rx[PKTBUFSRX];
42 struct cdmac_bd tx[TX_BUF_CNT];
43};
44
45/*
46 * DMA Buffer Descriptor alignment
47 *
48 * If the address contained in the Next Descriptor Pointer register is not
49 * 8-word aligned or reaches beyond the range of available memory, the SDMA
50 * halts processing and sets the CDMAC_BD_STCTRL_ERROR bit in the respective
51 * status register (tx_chnl_sts or rx_chnl_sts).
52 *
53 * [1]: [0]/ip_documentation/mpmc.pdf
54 * page 161, Next Descriptor Pointer
55 */
56static struct rtx_cdmac_bd cdmac_bd __aligned(32);
57
58#if defined(CONFIG_XILINX_440) || defined(CONFIG_XILINX_405)
59
60/*
61 * Indirect DCR access operations mi{ft}dcr_xilinx() espacialy
62 * for Xilinx PowerPC implementations on FPGA.
63 *
64 * FIXME: This part should go up to arch/powerpc -- but where?
65 */
66#include <asm/processor.h>
67#define XILINX_INDIRECT_DCR_ADDRESS_REG 0
68#define XILINX_INDIRECT_DCR_ACCESS_REG 1
69inline unsigned mifdcr_xilinx(const unsigned dcrn)
70{
71 mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
72 return mfdcr(XILINX_INDIRECT_DCR_ACCESS_REG);
73}
74inline void mitdcr_xilinx(const unsigned dcrn, int val)
75{
76 mtdcr(XILINX_INDIRECT_DCR_ADDRESS_REG, dcrn);
77 mtdcr(XILINX_INDIRECT_DCR_ACCESS_REG, val);
78}
79
80/* Xilinx Device Control Register (DCR) in/out accessors */
81inline unsigned ll_temac_xldcr_in32(phys_addr_t addr)
82{
83 return mifdcr_xilinx((const unsigned)addr);
84}
85inline void ll_temac_xldcr_out32(phys_addr_t addr, unsigned value)
86{
87 mitdcr_xilinx((const unsigned)addr, value);
88}
89
90void ll_temac_collect_xldcr_sdma_reg_addr(struct eth_device *dev)
91{
92 struct ll_temac *ll_temac = dev->priv;
93 phys_addr_t dmac_ctrl = ll_temac->ctrladdr;
94 phys_addr_t *ra = ll_temac->sdma_reg_addr;
95
96 ra[TX_NXTDESC_PTR] = dmac_ctrl + TX_NXTDESC_PTR;
97 ra[TX_CURBUF_ADDR] = dmac_ctrl + TX_CURBUF_ADDR;
98 ra[TX_CURBUF_LENGTH] = dmac_ctrl + TX_CURBUF_LENGTH;
99 ra[TX_CURDESC_PTR] = dmac_ctrl + TX_CURDESC_PTR;
100 ra[TX_TAILDESC_PTR] = dmac_ctrl + TX_TAILDESC_PTR;
101 ra[TX_CHNL_CTRL] = dmac_ctrl + TX_CHNL_CTRL;
102 ra[TX_IRQ_REG] = dmac_ctrl + TX_IRQ_REG;
103 ra[TX_CHNL_STS] = dmac_ctrl + TX_CHNL_STS;
104 ra[RX_NXTDESC_PTR] = dmac_ctrl + RX_NXTDESC_PTR;
105 ra[RX_CURBUF_ADDR] = dmac_ctrl + RX_CURBUF_ADDR;
106 ra[RX_CURBUF_LENGTH] = dmac_ctrl + RX_CURBUF_LENGTH;
107 ra[RX_CURDESC_PTR] = dmac_ctrl + RX_CURDESC_PTR;
108 ra[RX_TAILDESC_PTR] = dmac_ctrl + RX_TAILDESC_PTR;
109 ra[RX_CHNL_CTRL] = dmac_ctrl + RX_CHNL_CTRL;
110 ra[RX_IRQ_REG] = dmac_ctrl + RX_IRQ_REG;
111 ra[RX_CHNL_STS] = dmac_ctrl + RX_CHNL_STS;
112 ra[DMA_CONTROL_REG] = dmac_ctrl + DMA_CONTROL_REG;
113}
114
115#endif /* CONFIG_XILINX_440 || ONFIG_XILINX_405 */
116
117/* Xilinx Processor Local Bus (PLB) in/out accessors */
118inline unsigned ll_temac_xlplb_in32(phys_addr_t addr)
119{
120 return in_be32((void *)addr);
121}
122inline void ll_temac_xlplb_out32(phys_addr_t addr, unsigned value)
123{
124 out_be32((void *)addr, value);
125}
126
127/* collect all register addresses for Xilinx PLB in/out accessors */
128void ll_temac_collect_xlplb_sdma_reg_addr(struct eth_device *dev)
129{
130 struct ll_temac *ll_temac = dev->priv;
131 struct sdma_ctrl *sdma_ctrl = (void *)ll_temac->ctrladdr;
132 phys_addr_t *ra = ll_temac->sdma_reg_addr;
133
134 ra[TX_NXTDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_nxtdesc_ptr;
135 ra[TX_CURBUF_ADDR] = (phys_addr_t)&sdma_ctrl->tx_curbuf_addr;
136 ra[TX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->tx_curbuf_length;
137 ra[TX_CURDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_curdesc_ptr;
138 ra[TX_TAILDESC_PTR] = (phys_addr_t)&sdma_ctrl->tx_taildesc_ptr;
139 ra[TX_CHNL_CTRL] = (phys_addr_t)&sdma_ctrl->tx_chnl_ctrl;
140 ra[TX_IRQ_REG] = (phys_addr_t)&sdma_ctrl->tx_irq_reg;
141 ra[TX_CHNL_STS] = (phys_addr_t)&sdma_ctrl->tx_chnl_sts;
142 ra[RX_NXTDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_nxtdesc_ptr;
143 ra[RX_CURBUF_ADDR] = (phys_addr_t)&sdma_ctrl->rx_curbuf_addr;
144 ra[RX_CURBUF_LENGTH] = (phys_addr_t)&sdma_ctrl->rx_curbuf_length;
145 ra[RX_CURDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_curdesc_ptr;
146 ra[RX_TAILDESC_PTR] = (phys_addr_t)&sdma_ctrl->rx_taildesc_ptr;
147 ra[RX_CHNL_CTRL] = (phys_addr_t)&sdma_ctrl->rx_chnl_ctrl;
148 ra[RX_IRQ_REG] = (phys_addr_t)&sdma_ctrl->rx_irq_reg;
149 ra[RX_CHNL_STS] = (phys_addr_t)&sdma_ctrl->rx_chnl_sts;
150 ra[DMA_CONTROL_REG] = (phys_addr_t)&sdma_ctrl->dma_control_reg;
151}
152
153/* Check for TX and RX channel errors. */
154static inline int ll_temac_sdma_error(struct eth_device *dev)
155{
156 int err;
157 struct ll_temac *ll_temac = dev->priv;
158 phys_addr_t *ra = ll_temac->sdma_reg_addr;
159
160 err = ll_temac->in32(ra[TX_CHNL_STS]) & CHNL_STS_ERROR;
161 err |= ll_temac->in32(ra[RX_CHNL_STS]) & CHNL_STS_ERROR;
162
163 return err;
164}
165
166int ll_temac_init_sdma(struct eth_device *dev)
167{
168 struct ll_temac *ll_temac = dev->priv;
169 struct cdmac_bd *rx_dp;
170 struct cdmac_bd *tx_dp;
171 phys_addr_t *ra = ll_temac->sdma_reg_addr;
172 int i;
173
174 printf("%s: SDMA: %d Rx buffers, %d Tx buffers\n",
175 dev->name, PKTBUFSRX, TX_BUF_CNT);
176
177 /* Initialize the Rx Buffer descriptors */
178 for (i = 0; i < PKTBUFSRX; i++) {
179 rx_dp = &cdmac_bd.rx[i];
180 memset(rx_dp, 0, sizeof(*rx_dp));
181 rx_dp->next_p = rx_dp;
182 rx_dp->buf_len = PKTSIZE_ALIGN;
183 rx_dp->phys_buf_p = (u8 *)NetRxPackets[i];
184 flush_cache((u32)rx_dp->phys_buf_p, PKTSIZE_ALIGN);
185 }
186 flush_cache((u32)cdmac_bd.rx, sizeof(cdmac_bd.rx));
187
188 /* Initialize the TX Buffer Descriptors */
189 for (i = 0; i < TX_BUF_CNT; i++) {
190 tx_dp = &cdmac_bd.tx[i];
191 memset(tx_dp, 0, sizeof(*tx_dp));
192 tx_dp->next_p = tx_dp;
193 }
194 flush_cache((u32)cdmac_bd.tx, sizeof(cdmac_bd.tx));
195
196 /* Reset index counter to the Rx and Tx Buffer descriptors */
197 rx_idx = tx_idx = 0;
198
199 /* initial Rx DMA start by writing to respective TAILDESC_PTR */
200 ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
201 ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
202
203 return 0;
204}
205
206int ll_temac_halt_sdma(struct eth_device *dev)
207{
208 unsigned timeout = 50; /* 1usec * 50 = 50usec */
209 struct ll_temac *ll_temac = dev->priv;
210 phys_addr_t *ra = ll_temac->sdma_reg_addr;
211
212 /*
213 * Soft reset the DMA
214 *
215 * Quote from MPMC documentation: Writing a 1 to this field
216 * forces the DMA engine to shutdown and reset itself. After
217 * setting this bit, software must poll it until the bit is
218 * cleared by the DMA. This indicates that the reset process
219 * is done and the pipeline has been flushed.
220 */
221 ll_temac->out32(ra[DMA_CONTROL_REG], DMA_CONTROL_RESET);
222 while (timeout && (ll_temac->in32(ra[DMA_CONTROL_REG])
223 & DMA_CONTROL_RESET)) {
224 timeout--;
225 udelay(1);
226 }
227
228 if (!timeout) {
229 printf("%s: Timeout\n", __func__);
230 return -1;
231 }
232
233 return 0;
234}
235
236int ll_temac_reset_sdma(struct eth_device *dev)
237{
238 u32 r;
239 struct ll_temac *ll_temac = dev->priv;
240 phys_addr_t *ra = ll_temac->sdma_reg_addr;
241
242 /* Soft reset the DMA. */
243 if (ll_temac_halt_sdma(dev))
244 return -1;
245
246 /* Now clear the interrupts. */
247 r = ll_temac->in32(ra[TX_CHNL_CTRL]);
248 r &= ~CHNL_CTRL_IRQ_MASK;
249 ll_temac->out32(ra[TX_CHNL_CTRL], r);
250
251 r = ll_temac->in32(ra[RX_CHNL_CTRL]);
252 r &= ~CHNL_CTRL_IRQ_MASK;
253 ll_temac->out32(ra[RX_CHNL_CTRL], r);
254
255 /* Now ACK pending IRQs. */
256 ll_temac->out32(ra[TX_IRQ_REG], IRQ_REG_IRQ_MASK);
257 ll_temac->out32(ra[RX_IRQ_REG], IRQ_REG_IRQ_MASK);
258
259 /* Set tail-ptr mode, disable errors for both channels. */
260 ll_temac->out32(ra[DMA_CONTROL_REG],
261 /* Enable use of tail pointer register */
262 DMA_CONTROL_TPE |
263 /* Disable error when 2 or 4 bit coalesce cnt overfl */
264 DMA_CONTROL_RXOCEID |
265 /* Disable error when 2 or 4 bit coalesce cnt overfl */
266 DMA_CONTROL_TXOCEID);
267
268 return 0;
269}
270
271int ll_temac_recv_sdma(struct eth_device *dev)
272{
273 int length, pb_idx;
274 struct cdmac_bd *rx_dp = &cdmac_bd.rx[rx_idx];
275 struct ll_temac *ll_temac = dev->priv;
276 phys_addr_t *ra = ll_temac->sdma_reg_addr;
277
278 if (ll_temac_sdma_error(dev)) {
279
280 if (ll_temac_reset_sdma(dev))
281 return -1;
282
283 ll_temac_init_sdma(dev);
284 }
285
286 flush_cache((u32)rx_dp, sizeof(*rx_dp));
287
288 if (!(rx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED))
289 return 0;
290
291 if (rx_dp->sca.stctrl & (CDMAC_BD_STCTRL_SOP | CDMAC_BD_STCTRL_EOP)) {
292 pb_idx = rx_idx;
293 length = rx_dp->sca.app[4] & CDMAC_BD_APP4_RXBYTECNT_MASK;
294 } else {
295 pb_idx = -1;
296 length = 0;
297 printf("%s: Got part of package, unsupported (%x)\n",
298 __func__, rx_dp->sca.stctrl);
299 }
300
301 /* flip the buffer */
302 flush_cache((u32)rx_dp->phys_buf_p, length);
303
304 /* reset the current descriptor */
305 rx_dp->sca.stctrl = 0;
306 rx_dp->sca.app[4] = 0;
307 flush_cache((u32)rx_dp, sizeof(*rx_dp));
308
309 /* Find next empty buffer descriptor, preparation for next iteration */
310 rx_idx = (rx_idx + 1) % PKTBUFSRX;
311 rx_dp = &cdmac_bd.rx[rx_idx];
312 flush_cache((u32)rx_dp, sizeof(*rx_dp));
313
314 /* DMA start by writing to respective TAILDESC_PTR */
315 ll_temac->out32(ra[RX_CURDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
316 ll_temac->out32(ra[RX_TAILDESC_PTR], (int)&cdmac_bd.rx[rx_idx]);
317
318 if (length > 0 && pb_idx != -1)
319 NetReceive(NetRxPackets[pb_idx], length);
320
321 return 0;
322}
323
Stephan Linz458e4fe2012-05-22 12:18:09 +0000324int ll_temac_send_sdma(struct eth_device *dev, void *packet, int length)
Stephan Linze1fd4be2012-02-25 00:48:31 +0000325{
326 unsigned timeout = 50; /* 1usec * 50 = 50usec */
327 struct cdmac_bd *tx_dp = &cdmac_bd.tx[tx_idx];
328 struct ll_temac *ll_temac = dev->priv;
329 phys_addr_t *ra = ll_temac->sdma_reg_addr;
330
331 if (ll_temac_sdma_error(dev)) {
332
333 if (ll_temac_reset_sdma(dev))
334 return -1;
335
336 ll_temac_init_sdma(dev);
337 }
338
339 tx_dp->phys_buf_p = (u8 *)packet;
340 tx_dp->buf_len = length;
341 tx_dp->sca.stctrl = CDMAC_BD_STCTRL_SOP | CDMAC_BD_STCTRL_EOP |
342 CDMAC_BD_STCTRL_STOP_ON_END;
343
344 flush_cache((u32)packet, length);
345 flush_cache((u32)tx_dp, sizeof(*tx_dp));
346
347 /* DMA start by writing to respective TAILDESC_PTR */
348 ll_temac->out32(ra[TX_CURDESC_PTR], (int)tx_dp);
349 ll_temac->out32(ra[TX_TAILDESC_PTR], (int)tx_dp);
350
351 /* Find next empty buffer descriptor, preparation for next iteration */
352 tx_idx = (tx_idx + 1) % TX_BUF_CNT;
353 tx_dp = &cdmac_bd.tx[tx_idx];
354
355 do {
356 flush_cache((u32)tx_dp, sizeof(*tx_dp));
357 udelay(1);
358 } while (timeout-- && !(tx_dp->sca.stctrl & CDMAC_BD_STCTRL_COMPLETED));
359
360 if (!timeout) {
361 printf("%s: Timeout\n", __func__);
362 return -1;
363 }
364
365 return 0;
366}