synopsys_edac.c source code [linux/drivers/edac/synopsys_edac.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* Synopsys DDR ECC Driver
4	* This driver is based on ppc4xx_edac.c drivers
5	*
6	* Copyright (C) 2012 - 2014 Xilinx, Inc.
7	*/
8
9	#include <linux/edac.h>
10	#include <linux/module.h>
11	#include <linux/platform_device.h>
12	#include <linux/interrupt.h>
13	#include <linux/of.h>
14
15	#include "edac_module.h"
16
17	/ Number of cs_rows needed per memory controller /
18	#define SYNPS_EDAC_NR_CSROWS 1
19
20	/ Number of channels per memory controller /
21	#define SYNPS_EDAC_NR_CHANS 1
22
23	/ Granularity of reported error in bytes /
24	#define SYNPS_EDAC_ERR_GRAIN 1
25
26	#define SYNPS_EDAC_MSG_SIZE 256
27
28	#define SYNPS_EDAC_MOD_STRING "synps_edac"
29	#define SYNPS_EDAC_MOD_VER "1"
30
31	/ Synopsys DDR memory controller registers that are relevant to ECC /
32	#define CTRL_OFST 0x0
33	#define T_ZQ_OFST 0xA4
34
35	/ ECC control register /
36	#define ECC_CTRL_OFST 0xC4
37	/ ECC log register /
38	#define CE_LOG_OFST 0xC8
39	/ ECC address register /
40	#define CE_ADDR_OFST 0xCC
41	/ ECC data[31:0] register /
42	#define CE_DATA_31_0_OFST 0xD0
43
44	/ Uncorrectable error info registers /
45	#define UE_LOG_OFST 0xDC
46	#define UE_ADDR_OFST 0xE0
47	#define UE_DATA_31_0_OFST 0xE4
48
49	#define STAT_OFST 0xF0
50	#define SCRUB_OFST 0xF4
51
52	/ Control register bit field definitions /
53	#define CTRL_BW_MASK 0xC
54	#define CTRL_BW_SHIFT 2
55
56	#define DDRCTL_WDTH_16 1
57	#define DDRCTL_WDTH_32 0
58
59	/ ZQ register bit field definitions /
60	#define T_ZQ_DDRMODE_MASK 0x2
61
62	/ ECC control register bit field definitions /
63	#define ECC_CTRL_CLR_CE_ERR 0x2
64	#define ECC_CTRL_CLR_UE_ERR 0x1
65
66	/ ECC correctable/uncorrectable error log register definitions /
67	#define LOG_VALID 0x1
68	#define CE_LOG_BITPOS_MASK 0xFE
69	#define CE_LOG_BITPOS_SHIFT 1
70
71	/ ECC correctable/uncorrectable error address register definitions /
72	#define ADDR_COL_MASK 0xFFF
73	#define ADDR_ROW_MASK 0xFFFF000
74	#define ADDR_ROW_SHIFT 12
75	#define ADDR_BANK_MASK 0x70000000
76	#define ADDR_BANK_SHIFT 28
77
78	/ ECC statistic register definitions /
79	#define STAT_UECNT_MASK 0xFF
80	#define STAT_CECNT_MASK 0xFF00
81	#define STAT_CECNT_SHIFT 8
82
83	/ ECC scrub register definitions /
84	#define SCRUB_MODE_MASK 0x7
85	#define SCRUB_MODE_SECDED 0x4
86
87	/ DDR ECC Quirks /
88	#define DDR_ECC_INTR_SUPPORT BIT(0)
89	#define DDR_ECC_DATA_POISON_SUPPORT BIT(1)
90	#define DDR_ECC_INTR_SELF_CLEAR BIT(2)
91
92	/ ZynqMP Enhanced DDR memory controller registers that are relevant to ECC /
93	/ ECC Configuration Registers /
94	#define ECC_CFG0_OFST 0x70
95	#define ECC_CFG1_OFST 0x74
96
97	/ ECC Status Register /
98	#define ECC_STAT_OFST 0x78
99
100	/ ECC Clear Register /
101	#define ECC_CLR_OFST 0x7C
102
103	/ ECC Error count Register /
104	#define ECC_ERRCNT_OFST 0x80
105
106	/ ECC Corrected Error Address Register /
107	#define ECC_CEADDR0_OFST 0x84
108	#define ECC_CEADDR1_OFST 0x88
109
110	/ ECC Syndrome Registers /
111	#define ECC_CSYND0_OFST 0x8C
112	#define ECC_CSYND1_OFST 0x90
113	#define ECC_CSYND2_OFST 0x94
114
115	/ ECC Bit Mask0 Address Register /
116	#define ECC_BITMASK0_OFST 0x98
117	#define ECC_BITMASK1_OFST 0x9C
118	#define ECC_BITMASK2_OFST 0xA0
119
120	/ ECC UnCorrected Error Address Register /
121	#define ECC_UEADDR0_OFST 0xA4
122	#define ECC_UEADDR1_OFST 0xA8
123
124	/ ECC Syndrome Registers /
125	#define ECC_UESYND0_OFST 0xAC
126	#define ECC_UESYND1_OFST 0xB0
127	#define ECC_UESYND2_OFST 0xB4
128
129	/ ECC Poison Address Reg /
130	#define ECC_POISON0_OFST 0xB8
131	#define ECC_POISON1_OFST 0xBC
132
133	#define ECC_ADDRMAP0_OFFSET 0x200
134
135	/ Control register bitfield definitions /
136	#define ECC_CTRL_BUSWIDTH_MASK 0x3000
137	#define ECC_CTRL_BUSWIDTH_SHIFT 12
138	#define ECC_CTRL_CLR_CE_ERRCNT BIT(2)
139	#define ECC_CTRL_CLR_UE_ERRCNT BIT(3)
140
141	/ DDR Control Register width definitions /
142	#define DDRCTL_EWDTH_16 2
143	#define DDRCTL_EWDTH_32 1
144	#define DDRCTL_EWDTH_64 0
145
146	/ ECC status register definitions /
147	#define ECC_STAT_UECNT_MASK 0xF0000
148	#define ECC_STAT_UECNT_SHIFT 16
149	#define ECC_STAT_CECNT_MASK 0xF00
150	#define ECC_STAT_CECNT_SHIFT 8
151	#define ECC_STAT_BITNUM_MASK 0x7F
152
153	/ ECC error count register definitions /
154	#define ECC_ERRCNT_UECNT_MASK 0xFFFF0000
155	#define ECC_ERRCNT_UECNT_SHIFT 16
156	#define ECC_ERRCNT_CECNT_MASK 0xFFFF
157
158	/ DDR QOS Interrupt register definitions /
159	#define DDR_QOS_IRQ_STAT_OFST 0x20200
160	#define DDR_QOSUE_MASK 0x4
161	#define DDR_QOSCE_MASK 0x2
162	#define ECC_CE_UE_INTR_MASK 0x6
163	#define DDR_QOS_IRQ_EN_OFST 0x20208
164	#define DDR_QOS_IRQ_DB_OFST 0x2020C
165
166	/ DDR QOS Interrupt register definitions /
167	#define DDR_UE_MASK BIT(9)
168	#define DDR_CE_MASK BIT(8)
169
170	/ ECC Corrected Error Register Mask and Shifts/
171	#define ECC_CEADDR0_RW_MASK 0x3FFFF
172	#define ECC_CEADDR0_RNK_MASK BIT(24)
173	#define ECC_CEADDR1_BNKGRP_MASK 0x3000000
174	#define ECC_CEADDR1_BNKNR_MASK 0x70000
175	#define ECC_CEADDR1_BLKNR_MASK 0xFFF
176	#define ECC_CEADDR1_BNKGRP_SHIFT 24
177	#define ECC_CEADDR1_BNKNR_SHIFT 16
178
179	/ ECC Poison register shifts /
180	#define ECC_POISON0_RANK_SHIFT 24
181	#define ECC_POISON0_RANK_MASK BIT(24)
182	#define ECC_POISON0_COLUMN_SHIFT 0
183	#define ECC_POISON0_COLUMN_MASK 0xFFF
184	#define ECC_POISON1_BG_SHIFT 28
185	#define ECC_POISON1_BG_MASK 0x30000000
186	#define ECC_POISON1_BANKNR_SHIFT 24
187	#define ECC_POISON1_BANKNR_MASK 0x7000000
188	#define ECC_POISON1_ROW_SHIFT 0
189	#define ECC_POISON1_ROW_MASK 0x3FFFF
190
191	/ DDR Memory type defines /
192	#define MEM_TYPE_DDR3 0x1
193	#define MEM_TYPE_LPDDR3 0x8
194	#define MEM_TYPE_DDR2 0x4
195	#define MEM_TYPE_DDR4 0x10
196	#define MEM_TYPE_LPDDR4 0x20
197
198	/ DDRC Software control register /
199	#define DDRC_SWCTL 0x320
200
201	/ DDRC ECC CE & UE poison mask /
202	#define ECC_CEPOISON_MASK 0x3
203	#define ECC_UEPOISON_MASK 0x1
204
205	/ DDRC Device config masks /
206	#define DDRC_MSTR_CFG_MASK 0xC0000000
207	#define DDRC_MSTR_CFG_SHIFT 30
208	#define DDRC_MSTR_CFG_X4_MASK 0x0
209	#define DDRC_MSTR_CFG_X8_MASK 0x1
210	#define DDRC_MSTR_CFG_X16_MASK 0x2
211	#define DDRC_MSTR_CFG_X32_MASK 0x3
212
213	#define DDR_MAX_ROW_SHIFT 18
214	#define DDR_MAX_COL_SHIFT 14
215	#define DDR_MAX_BANK_SHIFT 3
216	#define DDR_MAX_BANKGRP_SHIFT 2
217
218	#define ROW_MAX_VAL_MASK 0xF
219	#define COL_MAX_VAL_MASK 0xF
220	#define BANK_MAX_VAL_MASK 0x1F
221	#define BANKGRP_MAX_VAL_MASK 0x1F
222	#define RANK_MAX_VAL_MASK 0x1F
223
224	#define ROW_B0_BASE 6
225	#define ROW_B1_BASE 7
226	#define ROW_B2_BASE 8
227	#define ROW_B3_BASE 9
228	#define ROW_B4_BASE 10
229	#define ROW_B5_BASE 11
230	#define ROW_B6_BASE 12
231	#define ROW_B7_BASE 13
232	#define ROW_B8_BASE 14
233	#define ROW_B9_BASE 15
234	#define ROW_B10_BASE 16
235	#define ROW_B11_BASE 17
236	#define ROW_B12_BASE 18
237	#define ROW_B13_BASE 19
238	#define ROW_B14_BASE 20
239	#define ROW_B15_BASE 21
240	#define ROW_B16_BASE 22
241	#define ROW_B17_BASE 23
242
243	#define COL_B2_BASE 2
244	#define COL_B3_BASE 3
245	#define COL_B4_BASE 4
246	#define COL_B5_BASE 5
247	#define COL_B6_BASE 6
248	#define COL_B7_BASE 7
249	#define COL_B8_BASE 8
250	#define COL_B9_BASE 9
251	#define COL_B10_BASE 10
252	#define COL_B11_BASE 11
253	#define COL_B12_BASE 12
254	#define COL_B13_BASE 13
255
256	#define BANK_B0_BASE 2
257	#define BANK_B1_BASE 3
258	#define BANK_B2_BASE 4
259
260	#define BANKGRP_B0_BASE 2
261	#define BANKGRP_B1_BASE 3
262
263	#define RANK_B0_BASE 6
264
265	/**
266	* struct ecc_error_info - ECC error log information.
267	* @row: Row number.
268	* @col: Column number.
269	* @bank: Bank number.
270	* @bitpos: Bit position.
271	* @data: Data causing the error.
272	* @bankgrpnr: Bank group number.
273	* @blknr: Block number.
274	*/
275	struct ecc_error_info {
276	u32 row;
277	u32 col;
278	u32 bank;
279	u32 bitpos;
280	u32 data;
281	u32 bankgrpnr;
282	u32 blknr;
283	};
284
285	/**
286	* struct synps_ecc_status - ECC status information to report.
287	* @ce_cnt: Correctable error count.
288	* @ue_cnt: Uncorrectable error count.
289	* @ceinfo: Correctable error log information.
290	* @ueinfo: Uncorrectable error log information.
291	*/
292	struct synps_ecc_status {
293	u32 ce_cnt;
294	u32 ue_cnt;
295	struct ecc_error_info ceinfo;
296	struct ecc_error_info ueinfo;
297	};
298
299	/**
300	* struct synps_edac_priv - DDR memory controller private instance data.
301	* @baseaddr: Base address of the DDR controller.
302	* @message: Buffer for framing the event specific info.
303	* @stat: ECC status information.
304	* @p_data: Platform data.
305	* @ce_cnt: Correctable Error count.
306	* @ue_cnt: Uncorrectable Error count.
307	* @poison_addr: Data poison address.
308	* @row_shift: Bit shifts for row bit.
309	* @col_shift: Bit shifts for column bit.
310	* @bank_shift: Bit shifts for bank bit.
311	* @bankgrp_shift: Bit shifts for bank group bit.
312	* @rank_shift: Bit shifts for rank bit.
313	*/
314	struct synps_edac_priv {
315	void __iomem *baseaddr;
316	char message[SYNPS_EDAC_MSG_SIZE];
317	struct synps_ecc_status stat;
318	const struct synps_platform_data *p_data;
319	u32 ce_cnt;
320	u32 ue_cnt;
321	#ifdef CONFIG_EDAC_DEBUG
322	ulong poison_addr;
323	u32 row_shift[`18`];
324	u32 col_shift[`14`];
325	u32 bank_shift[`3`];
326	u32 bankgrp_shift[`2`];
327	u32 rank_shift[`1`];
328	#endif
329	};
330
331	/**
332	* struct synps_platform_data - synps platform data structure.
333	* @get_error_info: Get EDAC error info.
334	* @get_mtype: Get mtype.
335	* @get_dtype: Get dtype.
336	* @get_ecc_state: Get ECC state.
337	* @quirks: To differentiate IPs.
338	*/
339	struct synps_platform_data {
340	int (get_error_info)(struct* synps_edac_priv *priv);
341	enum mem_type (get_mtype)(const* void __iomem *base);
342	enum dev_type (get_dtype)(const* void __iomem *base);
343	bool (get_ecc_state)(void* __iomem *base);
344	int quirks;
345	};
346
347	/**
348	* zynq_get_error_info - Get the current ECC error info.
349	* @priv: DDR memory controller private instance data.
350	*
351	* Return: one if there is no error, otherwise zero.
352	*/
353	static int zynq_get_error_info(struct synps_edac_priv *priv)
354	{
355	struct synps_ecc_status *p;
356	u32 regval, clearval = `0`;
357	void __iomem *base;
358
359	base = priv->baseaddr;
360	p = &priv->stat;
361
362	regval = readl(addr: base + STAT_OFST);
363	if (!regval)
364	return `1`;
365
366	p->ce_cnt = (regval & STAT_CECNT_MASK) >> STAT_CECNT_SHIFT;
367	p->ue_cnt = regval & STAT_UECNT_MASK;
368
369	regval = readl(addr: base + CE_LOG_OFST);
370	if (!(p->ce_cnt && (regval & LOG_VALID)))
371	goto ue_err;
372
373	p->ceinfo.bitpos = (regval & CE_LOG_BITPOS_MASK) >> CE_LOG_BITPOS_SHIFT;
374	regval = readl(addr: base + CE_ADDR_OFST);
375	p->ceinfo.row = (regval & ADDR_ROW_MASK) >> ADDR_ROW_SHIFT;
376	p->ceinfo.col = regval & ADDR_COL_MASK;
377	p->ceinfo.bank = (regval & ADDR_BANK_MASK) >> ADDR_BANK_SHIFT;
378	p->ceinfo.data = readl(addr: base + CE_DATA_31_0_OFST);
379	edac_dbg(`3`, "CE bit position: %d data: %d\n", p->ceinfo.bitpos,
380	p->ceinfo.data);
381	clearval = ECC_CTRL_CLR_CE_ERR;
382
383	ue_err:
384	regval = readl(addr: base + UE_LOG_OFST);
385	if (!(p->ue_cnt && (regval & LOG_VALID)))
386	goto out;
387
388	regval = readl(addr: base + UE_ADDR_OFST);
389	p->ueinfo.row = (regval & ADDR_ROW_MASK) >> ADDR_ROW_SHIFT;
390	p->ueinfo.col = regval & ADDR_COL_MASK;
391	p->ueinfo.bank = (regval & ADDR_BANK_MASK) >> ADDR_BANK_SHIFT;
392	p->ueinfo.data = readl(addr: base + UE_DATA_31_0_OFST);
393	clearval \|= ECC_CTRL_CLR_UE_ERR;
394
395	out:
396	writel(val: clearval, addr: base + ECC_CTRL_OFST);
397	writel(val: `0x0`, addr: base + ECC_CTRL_OFST);
398
399	return `0`;
400	}
401
402	/**
403	* zynqmp_get_error_info - Get the current ECC error info.
404	* @priv: DDR memory controller private instance data.
405	*
406	* Return: one if there is no error otherwise returns zero.
407	*/
408	static int zynqmp_get_error_info(struct synps_edac_priv *priv)
409	{
410	struct synps_ecc_status *p;
411	u32 regval, clearval = `0`;
412	void __iomem *base;
413
414	base = priv->baseaddr;
415	p = &priv->stat;
416
417	regval = readl(addr: base + ECC_ERRCNT_OFST);
418	p->ce_cnt = regval & ECC_ERRCNT_CECNT_MASK;
419	p->ue_cnt = (regval & ECC_ERRCNT_UECNT_MASK) >> ECC_ERRCNT_UECNT_SHIFT;
420	if (!p->ce_cnt)
421	goto ue_err;
422
423	regval = readl(addr: base + ECC_STAT_OFST);
424	if (!regval)
425	return `1`;
426
427	p->ceinfo.bitpos = (regval & ECC_STAT_BITNUM_MASK);
428
429	regval = readl(addr: base + ECC_CEADDR0_OFST);
430	p->ceinfo.row = (regval & ECC_CEADDR0_RW_MASK);
431	regval = readl(addr: base + ECC_CEADDR1_OFST);
432	p->ceinfo.bank = (regval & ECC_CEADDR1_BNKNR_MASK) >>
433	ECC_CEADDR1_BNKNR_SHIFT;
434	p->ceinfo.bankgrpnr = (regval & ECC_CEADDR1_BNKGRP_MASK) >>
435	ECC_CEADDR1_BNKGRP_SHIFT;
436	p->ceinfo.blknr = (regval & ECC_CEADDR1_BLKNR_MASK);
437	p->ceinfo.data = readl(addr: base + ECC_CSYND0_OFST);
438	edac_dbg(`2`, "ECCCSYN0: 0x%08X ECCCSYN1: 0x%08X ECCCSYN2: 0x%08X\n",
439	readl(base + ECC_CSYND0_OFST), readl(base + ECC_CSYND1_OFST),
440	readl(base + ECC_CSYND2_OFST));
441	ue_err:
442	if (!p->ue_cnt)
443	goto out;
444
445	regval = readl(addr: base + ECC_UEADDR0_OFST);
446	p->ueinfo.row = (regval & ECC_CEADDR0_RW_MASK);
447	regval = readl(addr: base + ECC_UEADDR1_OFST);
448	p->ueinfo.bankgrpnr = (regval & ECC_CEADDR1_BNKGRP_MASK) >>
449	ECC_CEADDR1_BNKGRP_SHIFT;
450	p->ueinfo.bank = (regval & ECC_CEADDR1_BNKNR_MASK) >>
451	ECC_CEADDR1_BNKNR_SHIFT;
452	p->ueinfo.blknr = (regval & ECC_CEADDR1_BLKNR_MASK);
453	p->ueinfo.data = readl(addr: base + ECC_UESYND0_OFST);
454	out:
455	clearval = ECC_CTRL_CLR_CE_ERR \| ECC_CTRL_CLR_CE_ERRCNT;
456	clearval \|= ECC_CTRL_CLR_UE_ERR \| ECC_CTRL_CLR_UE_ERRCNT;
457	writel(val: clearval, addr: base + ECC_CLR_OFST);
458	writel(val: `0x0`, addr: base + ECC_CLR_OFST);
459
460	return `0`;
461	}
462
463	/**
464	* handle_error - Handle Correctable and Uncorrectable errors.
465	* @mci: EDAC memory controller instance.
466	* @p: Synopsys ECC status structure.
467	*
468	* Handles ECC correctable and uncorrectable errors.
469	*/
470	static void handle_error(struct mem_ctl_info mci, struct* synps_ecc_status *p)
471	{
472	struct synps_edac_priv *priv = mci->pvt_info;
473	struct ecc_error_info *pinf;
474
475	if (p->ce_cnt) {
476	pinf = &p->ceinfo;
477	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT) {
478	snprintf(buf: priv->message, SYNPS_EDAC_MSG_SIZE,
479	fmt: "DDR ECC error type:%s Row %d Bank %d BankGroup Number %d Block Number %d Bit Position: %d Data: 0x%08x",
480	"CE", pinf->row, pinf->bank,
481	pinf->bankgrpnr, pinf->blknr,
482	pinf->bitpos, pinf->data);
483	} else {
484	snprintf(buf: priv->message, SYNPS_EDAC_MSG_SIZE,
485	fmt: "DDR ECC error type:%s Row %d Bank %d Col %d Bit Position: %d Data: 0x%08x",
486	"CE", pinf->row, pinf->bank, pinf->col,
487	pinf->bitpos, pinf->data);
488	}
489
490	edac_mc_handle_error(type: HW_EVENT_ERR_CORRECTED, mci,
491	error_count: p->ce_cnt, page_frame_number: `0`, offset_in_page: `0`, syndrome: `0`, top_layer: `0`, mid_layer: `0`, low_layer: -`1`,
492	msg: priv->message, other_detail: "");
493	}
494
495	if (p->ue_cnt) {
496	pinf = &p->ueinfo;
497	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT) {
498	snprintf(buf: priv->message, SYNPS_EDAC_MSG_SIZE,
499	fmt: "DDR ECC error type :%s Row %d Bank %d BankGroup Number %d Block Number %d",
500	"UE", pinf->row, pinf->bank,
501	pinf->bankgrpnr, pinf->blknr);
502	} else {
503	snprintf(buf: priv->message, SYNPS_EDAC_MSG_SIZE,
504	fmt: "DDR ECC error type :%s Row %d Bank %d Col %d ",
505	"UE", pinf->row, pinf->bank, pinf->col);
506	}
507
508	edac_mc_handle_error(type: HW_EVENT_ERR_UNCORRECTED, mci,
509	error_count: p->ue_cnt, page_frame_number: `0`, offset_in_page: `0`, syndrome: `0`, top_layer: `0`, mid_layer: `0`, low_layer: -`1`,
510	msg: priv->message, other_detail: "");
511	}
512
513	memset(p, `0`, sizeof(*p));
514	}
515
516	static void enable_intr(struct synps_edac_priv *priv)
517	{
518	/ Enable UE/CE Interrupts /
519	if (priv->p_data->quirks & DDR_ECC_INTR_SELF_CLEAR)
520	writel(DDR_UE_MASK \| DDR_CE_MASK,
521	addr: priv->baseaddr + ECC_CLR_OFST);
522	else
523	writel(DDR_QOSUE_MASK \| DDR_QOSCE_MASK,
524	addr: priv->baseaddr + DDR_QOS_IRQ_EN_OFST);
525
526	}
527
528	static void disable_intr(struct synps_edac_priv *priv)
529	{
530	/ Disable UE/CE Interrupts /
531	if (priv->p_data->quirks & DDR_ECC_INTR_SELF_CLEAR)
532	writel(val: `0x0`, addr: priv->baseaddr + ECC_CLR_OFST);
533	else
534	writel(DDR_QOSUE_MASK \| DDR_QOSCE_MASK,
535	addr: priv->baseaddr + DDR_QOS_IRQ_DB_OFST);
536	}
537
538	/**
539	* intr_handler - Interrupt Handler for ECC interrupts.
540	* @irq: IRQ number.
541	* @dev_id: Device ID.
542	*
543	* Return: IRQ_NONE, if interrupt not set or IRQ_HANDLED otherwise.
544	*/
545	static irqreturn_t intr_handler(int irq, void *dev_id)
546	{
547	const struct synps_platform_data *p_data;
548	struct mem_ctl_info *mci = dev_id;
549	struct synps_edac_priv *priv;
550	int status, regval;
551
552	priv = mci->pvt_info;
553	p_data = priv->p_data;
554
555	/*
556	* v3.0 of the controller has the ce/ue bits cleared automatically,
557	* so this condition does not apply.
558	*/
559	if (!(priv->p_data->quirks & DDR_ECC_INTR_SELF_CLEAR)) {
560	regval = readl(addr: priv->baseaddr + DDR_QOS_IRQ_STAT_OFST);
561	regval &= (DDR_QOSCE_MASK \| DDR_QOSUE_MASK);
562	if (!(regval & ECC_CE_UE_INTR_MASK))
563	return IRQ_NONE;
564	}
565
566	status = p_data->get_error_info(priv);
567	if (status)
568	return IRQ_NONE;
569
570	priv->ce_cnt += priv->stat.ce_cnt;
571	priv->ue_cnt += priv->stat.ue_cnt;
572	handle_error(mci, p: &priv->stat);
573
574	edac_dbg(`3`, "Total error count CE %d UE %d\n",
575	priv->ce_cnt, priv->ue_cnt);
576	/ v3.0 of the controller does not have this register /
577	if (!(priv->p_data->quirks & DDR_ECC_INTR_SELF_CLEAR))
578	writel(val: regval, addr: priv->baseaddr + DDR_QOS_IRQ_STAT_OFST);
579	else
580	enable_intr(priv);
581
582	return IRQ_HANDLED;
583	}
584
585	/**
586	* check_errors - Check controller for ECC errors.
587	* @mci: EDAC memory controller instance.
588	*
589	* Check and post ECC errors. Called by the polling thread.
590	*/
591	static void check_errors(struct mem_ctl_info *mci)
592	{
593	const struct synps_platform_data *p_data;
594	struct synps_edac_priv *priv;
595	int status;
596
597	priv = mci->pvt_info;
598	p_data = priv->p_data;
599
600	status = p_data->get_error_info(priv);
601	if (status)
602	return;
603
604	priv->ce_cnt += priv->stat.ce_cnt;
605	priv->ue_cnt += priv->stat.ue_cnt;
606	handle_error(mci, p: &priv->stat);
607
608	edac_dbg(`3`, "Total error count CE %d UE %d\n",
609	priv->ce_cnt, priv->ue_cnt);
610	}
611
612	/**
613	* zynq_get_dtype - Return the controller memory width.
614	* @base: DDR memory controller base address.
615	*
616	* Get the EDAC device type width appropriate for the current controller
617	* configuration.
618	*
619	* Return: a device type width enumeration.
620	*/
621	static enum dev_type zynq_get_dtype(const void __iomem *base)
622	{
623	enum dev_type dt;
624	u32 width;
625
626	width = readl(addr: base + CTRL_OFST);
627	width = (width & CTRL_BW_MASK) >> CTRL_BW_SHIFT;
628
629	switch (width) {
630	case DDRCTL_WDTH_16:
631	dt = DEV_X2;
632	break;
633	case DDRCTL_WDTH_32:
634	dt = DEV_X4;
635	break;
636	default:
637	dt = DEV_UNKNOWN;
638	}
639
640	return dt;
641	}
642
643	/**
644	* zynqmp_get_dtype - Return the controller memory width.
645	* @base: DDR memory controller base address.
646	*
647	* Get the EDAC device type width appropriate for the current controller
648	* configuration.
649	*
650	* Return: a device type width enumeration.
651	*/
652	static enum dev_type zynqmp_get_dtype(const void __iomem *base)
653	{
654	enum dev_type dt;
655	u32 width;
656
657	width = readl(addr: base + CTRL_OFST);
658	width = (width & ECC_CTRL_BUSWIDTH_MASK) >> ECC_CTRL_BUSWIDTH_SHIFT;
659	switch (width) {
660	case DDRCTL_EWDTH_16:
661	dt = DEV_X2;
662	break;
663	case DDRCTL_EWDTH_32:
664	dt = DEV_X4;
665	break;
666	case DDRCTL_EWDTH_64:
667	dt = DEV_X8;
668	break;
669	default:
670	dt = DEV_UNKNOWN;
671	}
672
673	return dt;
674	}
675
676	/**
677	* zynq_get_ecc_state - Return the controller ECC enable/disable status.
678	* @base: DDR memory controller base address.
679	*
680	* Get the ECC enable/disable status of the controller.
681	*
682	* Return: true if enabled, otherwise false.
683	*/
684	static bool zynq_get_ecc_state(void __iomem *base)
685	{
686	enum dev_type dt;
687	u32 ecctype;
688
689	dt = zynq_get_dtype(base);
690	if (dt == DEV_UNKNOWN)
691	return false;
692
693	ecctype = readl(addr: base + SCRUB_OFST) & SCRUB_MODE_MASK;
694	if ((ecctype == SCRUB_MODE_SECDED) && (dt == DEV_X2))
695	return true;
696
697	return false;
698	}
699
700	/**
701	* zynqmp_get_ecc_state - Return the controller ECC enable/disable status.
702	* @base: DDR memory controller base address.
703	*
704	* Get the ECC enable/disable status for the controller.
705	*
706	* Return: a ECC status boolean i.e true/false - enabled/disabled.
707	*/
708	static bool zynqmp_get_ecc_state(void __iomem *base)
709	{
710	enum dev_type dt;
711	u32 ecctype;
712
713	dt = zynqmp_get_dtype(base);
714	if (dt == DEV_UNKNOWN)
715	return false;
716
717	ecctype = readl(addr: base + ECC_CFG0_OFST) & SCRUB_MODE_MASK;
718	if ((ecctype == SCRUB_MODE_SECDED) &&
719	((dt == DEV_X2) \|\| (dt == DEV_X4) \|\| (dt == DEV_X8)))
720	return true;
721
722	return false;
723	}
724
725	/**
726	* get_memsize - Read the size of the attached memory device.
727	*
728	* Return: the memory size in bytes.
729	*/
730	static u32 get_memsize(void)
731	{
732	struct sysinfo inf;
733
734	si_meminfo(val: &inf);
735
736	return inf.totalram * inf.mem_unit;
737	}
738
739	/**
740	* zynq_get_mtype - Return the controller memory type.
741	* @base: Synopsys ECC status structure.
742	*
743	* Get the EDAC memory type appropriate for the current controller
744	* configuration.
745	*
746	* Return: a memory type enumeration.
747	*/
748	static enum mem_type zynq_get_mtype(const void __iomem *base)
749	{
750	enum mem_type mt;
751	u32 memtype;
752
753	memtype = readl(addr: base + T_ZQ_OFST);
754
755	if (memtype & T_ZQ_DDRMODE_MASK)
756	mt = MEM_DDR3;
757	else
758	mt = MEM_DDR2;
759
760	return mt;
761	}
762
763	/**
764	* zynqmp_get_mtype - Returns controller memory type.
765	* @base: Synopsys ECC status structure.
766	*
767	* Get the EDAC memory type appropriate for the current controller
768	* configuration.
769	*
770	* Return: a memory type enumeration.
771	*/
772	static enum mem_type zynqmp_get_mtype(const void __iomem *base)
773	{
774	enum mem_type mt;
775	u32 memtype;
776
777	memtype = readl(addr: base + CTRL_OFST);
778
779	if ((memtype & MEM_TYPE_DDR3) \|\| (memtype & MEM_TYPE_LPDDR3))
780	mt = MEM_DDR3;
781	else if (memtype & MEM_TYPE_DDR2)
782	mt = MEM_RDDR2;
783	else if ((memtype & MEM_TYPE_LPDDR4) \|\| (memtype & MEM_TYPE_DDR4))
784	mt = MEM_DDR4;
785	else
786	mt = MEM_EMPTY;
787
788	return mt;
789	}
790
791	/**
792	* init_csrows - Initialize the csrow data.
793	* @mci: EDAC memory controller instance.
794	*
795	* Initialize the chip select rows associated with the EDAC memory
796	* controller instance.
797	*/
798	static void init_csrows(struct mem_ctl_info *mci)
799	{
800	struct synps_edac_priv *priv = mci->pvt_info;
801	const struct synps_platform_data *p_data;
802	struct csrow_info *csi;
803	struct dimm_info *dimm;
804	u32 size, row;
805	int j;
806
807	p_data = priv->p_data;
808
809	for (row = `0`; row < mci->nr_csrows; row++) {
810	csi = mci->csrows[row];
811	size = get_memsize();
812
813	for (j = `0`; j < csi->nr_channels; j++) {
814	dimm = csi->channels[j]->dimm;
815	dimm->edac_mode = EDAC_SECDED;
816	dimm->mtype = p_data->get_mtype(priv->baseaddr);
817	dimm->nr_pages = (size >> PAGE_SHIFT) / csi->nr_channels;
818	dimm->grain = SYNPS_EDAC_ERR_GRAIN;
819	dimm->dtype = p_data->get_dtype(priv->baseaddr);
820	}
821	}
822	}
823
824	/**
825	* mc_init - Initialize one driver instance.
826	* @mci: EDAC memory controller instance.
827	* @pdev: platform device.
828	*
829	* Perform initialization of the EDAC memory controller instance and
830	* related driver-private data associated with the memory controller the
831	* instance is bound to.
832	*/
833	static void mc_init(struct mem_ctl_info mci, struct* platform_device *pdev)
834	{
835	struct synps_edac_priv *priv;
836
837	mci->pdev = &pdev->dev;
838	priv = mci->pvt_info;
839	platform_set_drvdata(pdev, data: mci);
840
841	/ Initialize controller capabilities and configuration /
842	mci->mtype_cap = MEM_FLAG_DDR3 \| MEM_FLAG_DDR2;
843	mci->edac_ctl_cap = EDAC_FLAG_NONE \| EDAC_FLAG_SECDED;
844	mci->scrub_cap = SCRUB_HW_SRC;
845	mci->scrub_mode = SCRUB_NONE;
846
847	mci->edac_cap = EDAC_FLAG_SECDED;
848	mci->ctl_name = "synps_ddr_controller";
849	mci->dev_name = SYNPS_EDAC_MOD_STRING;
850	mci->mod_name = SYNPS_EDAC_MOD_VER;
851
852	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT) {
853	edac_op_state = EDAC_OPSTATE_INT;
854	} else {
855	edac_op_state = EDAC_OPSTATE_POLL;
856	mci->edac_check = check_errors;
857	}
858
859	mci->ctl_page_to_phys = NULL;
860
861	init_csrows(mci);
862	}
863
864	static int setup_irq(struct mem_ctl_info *mci,
865	struct platform_device *pdev)
866	{
867	struct synps_edac_priv *priv = mci->pvt_info;
868	int ret, irq;
869
870	irq = platform_get_irq(pdev, `0`);
871	if (irq < `0`) {
872	edac_printk(KERN_ERR, EDAC_MC,
873	"No IRQ %d in DT\n", irq);
874	return irq;
875	}
876
877	ret = devm_request_irq(dev: &pdev->dev, irq, handler: intr_handler,
878	irqflags: `0`, devname: dev_name(dev: &pdev->dev), dev_id: mci);
879	if (ret < `0`) {
880	edac_printk(KERN_ERR, EDAC_MC, "Failed to request IRQ\n");
881	return ret;
882	}
883
884	enable_intr(priv);
885
886	return `0`;
887	}
888
889	static const struct synps_platform_data zynq_edac_def = {
890	.get_error_info = zynq_get_error_info,
891	.get_mtype = zynq_get_mtype,
892	.get_dtype = zynq_get_dtype,
893	.get_ecc_state = zynq_get_ecc_state,
894	.quirks = `0`,
895	};
896
897	static const struct synps_platform_data zynqmp_edac_def = {
898	.get_error_info = zynqmp_get_error_info,
899	.get_mtype = zynqmp_get_mtype,
900	.get_dtype = zynqmp_get_dtype,
901	.get_ecc_state = zynqmp_get_ecc_state,
902	.quirks = (DDR_ECC_INTR_SUPPORT
903	#ifdef CONFIG_EDAC_DEBUG
904	\| DDR_ECC_DATA_POISON_SUPPORT
905	#endif
906	),
907	};
908
909	static const struct synps_platform_data synopsys_edac_def = {
910	.get_error_info = zynqmp_get_error_info,
911	.get_mtype = zynqmp_get_mtype,
912	.get_dtype = zynqmp_get_dtype,
913	.get_ecc_state = zynqmp_get_ecc_state,
914	.quirks = (DDR_ECC_INTR_SUPPORT \| DDR_ECC_INTR_SELF_CLEAR
915	#ifdef CONFIG_EDAC_DEBUG
916	\| DDR_ECC_DATA_POISON_SUPPORT
917	#endif
918	),
919	};
920
921
922	static const struct of_device_id synps_edac_match[] = {
923	{
924	.compatible = "xlnx,zynq-ddrc-a05",
925	.data = (void *)&zynq_edac_def
926	},
927	{
928	.compatible = "xlnx,zynqmp-ddrc-2.40a",
929	.data = (void *)&zynqmp_edac_def
930	},
931	{
932	.compatible = "snps,ddrc-3.80a",
933	.data = (void *)&synopsys_edac_def
934	},
935	{
936	/ end of table /
937	}
938	};
939
940	MODULE_DEVICE_TABLE(of, synps_edac_match);
941
942	#ifdef CONFIG_EDAC_DEBUG
943	#define to_mci(k) container_of(k, struct mem_ctl_info, dev)
944
945	/**
946	* ddr_poison_setup - Update poison registers.
947	* @priv: DDR memory controller private instance data.
948	*
949	* Update poison registers as per DDR mapping.
950	* Return: none.
951	*/
952	static void ddr_poison_setup(struct synps_edac_priv *priv)
953	{
954	int col = `0`, row = `0`, bank = `0`, bankgrp = `0`, rank = `0`, regval;
955	int index;
956	ulong hif_addr = `0`;
957
958	hif_addr = priv->poison_addr >> `3`;
959
960	for (index = `0`; index < DDR_MAX_ROW_SHIFT; index++) {
961	if (priv->row_shift[index])
962	row \|= (((hif_addr >> priv->row_shift[index]) &
963	BIT(`0`)) << index);
964	else
965	break;
966	}
967
968	for (index = `0`; index < DDR_MAX_COL_SHIFT; index++) {
969	if (priv->col_shift[index] \|\| index < `3`)
970	col \|= (((hif_addr >> priv->col_shift[index]) &
971	BIT(`0`)) << index);
972	else
973	break;
974	}
975
976	for (index = `0`; index < DDR_MAX_BANK_SHIFT; index++) {
977	if (priv->bank_shift[index])
978	bank \|= (((hif_addr >> priv->bank_shift[index]) &
979	BIT(`0`)) << index);
980	else
981	break;
982	}
983
984	for (index = `0`; index < DDR_MAX_BANKGRP_SHIFT; index++) {
985	if (priv->bankgrp_shift[index])
986	bankgrp \|= (((hif_addr >> priv->bankgrp_shift[index])
987	& BIT(`0`)) << index);
988	else
989	break;
990	}
991
992	if (priv->rank_shift[`0`])
993	rank = (hif_addr >> priv->rank_shift[`0`]) & BIT(`0`);
994
995	regval = (rank << ECC_POISON0_RANK_SHIFT) & ECC_POISON0_RANK_MASK;
996	regval \|= (col << ECC_POISON0_COLUMN_SHIFT) & ECC_POISON0_COLUMN_MASK;
997	writel(val: regval, addr: priv->baseaddr + ECC_POISON0_OFST);
998
999	regval = (bankgrp << ECC_POISON1_BG_SHIFT) & ECC_POISON1_BG_MASK;
1000	regval \|= (bank << ECC_POISON1_BANKNR_SHIFT) & ECC_POISON1_BANKNR_MASK;
1001	regval \|= (row << ECC_POISON1_ROW_SHIFT) & ECC_POISON1_ROW_MASK;
1002	writel(val: regval, addr: priv->baseaddr + ECC_POISON1_OFST);
1003	}
1004
1005	static ssize_t inject_data_error_show(struct device *dev,
1006	struct device_attribute *mattr,
1007	char *data)
1008	{
1009	struct mem_ctl_info *mci = to_mci(dev);
1010	struct synps_edac_priv *priv = mci->pvt_info;
1011
1012	return sprintf(buf: data, fmt: "Poison0 Addr: 0x%08x\n\rPoison1 Addr: 0x%08x\n\r"
1013	"Error injection Address: 0x%lx\n\r",
1014	readl(addr: priv->baseaddr + ECC_POISON0_OFST),
1015	readl(addr: priv->baseaddr + ECC_POISON1_OFST),
1016	priv->poison_addr);
1017	}
1018
1019	static ssize_t inject_data_error_store(struct device *dev,
1020	struct device_attribute *mattr,
1021	const char *data, size_t count)
1022	{
1023	struct mem_ctl_info *mci = to_mci(dev);
1024	struct synps_edac_priv *priv = mci->pvt_info;
1025
1026	if (kstrtoul(s: data, base: `0`, res: &priv->poison_addr))
1027	return -EINVAL;
1028
1029	ddr_poison_setup(priv);
1030
1031	return count;
1032	}
1033
1034	static ssize_t inject_data_poison_show(struct device *dev,
1035	struct device_attribute *mattr,
1036	char *data)
1037	{
1038	struct mem_ctl_info *mci = to_mci(dev);
1039	struct synps_edac_priv *priv = mci->pvt_info;
1040
1041	return sprintf(buf: data, fmt: "Data Poisoning: %s\n\r",
1042	(((readl(addr: priv->baseaddr + ECC_CFG1_OFST)) & `0x3`) == `0x3`)
1043	? ("Correctable Error") : ("UnCorrectable Error"));
1044	}
1045
1046	static ssize_t inject_data_poison_store(struct device *dev,
1047	struct device_attribute *mattr,
1048	const char *data, size_t count)
1049	{
1050	struct mem_ctl_info *mci = to_mci(dev);
1051	struct synps_edac_priv *priv = mci->pvt_info;
1052
1053	writel(val: `0`, addr: priv->baseaddr + DDRC_SWCTL);
1054	if (strncmp(data, "CE", `2`) == `0`)
1055	writel(ECC_CEPOISON_MASK, addr: priv->baseaddr + ECC_CFG1_OFST);
1056	else
1057	writel(ECC_UEPOISON_MASK, addr: priv->baseaddr + ECC_CFG1_OFST);
1058	writel(val: `1`, addr: priv->baseaddr + DDRC_SWCTL);
1059
1060	return count;
1061	}
1062
1063	static DEVICE_ATTR_RW(inject_data_error);
1064	static DEVICE_ATTR_RW(inject_data_poison);
1065
1066	static int edac_create_sysfs_attributes(struct mem_ctl_info *mci)
1067	{
1068	int rc;
1069
1070	rc = device_create_file(device: &mci->dev, entry: &dev_attr_inject_data_error);
1071	if (rc < `0`)
1072	return rc;
1073	rc = device_create_file(device: &mci->dev, entry: &dev_attr_inject_data_poison);
1074	if (rc < `0`)
1075	return rc;
1076	return `0`;
1077	}
1078
1079	static void edac_remove_sysfs_attributes(struct mem_ctl_info *mci)
1080	{
1081	device_remove_file(dev: &mci->dev, attr: &dev_attr_inject_data_error);
1082	device_remove_file(dev: &mci->dev, attr: &dev_attr_inject_data_poison);
1083	}
1084
1085	static void setup_row_address_map(struct synps_edac_priv priv, u32 addrmap)
1086	{
1087	u32 addrmap_row_b2_10;
1088	int index;
1089
1090	priv->row_shift[`0`] = (addrmap[`5`] & ROW_MAX_VAL_MASK) + ROW_B0_BASE;
1091	priv->row_shift[`1`] = ((addrmap[`5`] >> `8`) &
1092	ROW_MAX_VAL_MASK) + ROW_B1_BASE;
1093
1094	addrmap_row_b2_10 = (addrmap[`5`] >> `16`) & ROW_MAX_VAL_MASK;
1095	if (addrmap_row_b2_10 != ROW_MAX_VAL_MASK) {
1096	for (index = `2`; index < `11`; index++)
1097	priv->row_shift[index] = addrmap_row_b2_10 +
1098	index + ROW_B0_BASE;
1099
1100	} else {
1101	priv->row_shift[`2`] = (addrmap[`9`] &
1102	ROW_MAX_VAL_MASK) + ROW_B2_BASE;
1103	priv->row_shift[`3`] = ((addrmap[`9`] >> `8`) &
1104	ROW_MAX_VAL_MASK) + ROW_B3_BASE;
1105	priv->row_shift[`4`] = ((addrmap[`9`] >> `16`) &
1106	ROW_MAX_VAL_MASK) + ROW_B4_BASE;
1107	priv->row_shift[`5`] = ((addrmap[`9`] >> `24`) &
1108	ROW_MAX_VAL_MASK) + ROW_B5_BASE;
1109	priv->row_shift[`6`] = (addrmap[`10`] &
1110	ROW_MAX_VAL_MASK) + ROW_B6_BASE;
1111	priv->row_shift[`7`] = ((addrmap[`10`] >> `8`) &
1112	ROW_MAX_VAL_MASK) + ROW_B7_BASE;
1113	priv->row_shift[`8`] = ((addrmap[`10`] >> `16`) &
1114	ROW_MAX_VAL_MASK) + ROW_B8_BASE;
1115	priv->row_shift[`9`] = ((addrmap[`10`] >> `24`) &
1116	ROW_MAX_VAL_MASK) + ROW_B9_BASE;
1117	priv->row_shift[`10`] = (addrmap[`11`] &
1118	ROW_MAX_VAL_MASK) + ROW_B10_BASE;
1119	}
1120
1121	priv->row_shift[`11`] = (((addrmap[`5`] >> `24`) & ROW_MAX_VAL_MASK) ==
1122	ROW_MAX_VAL_MASK) ? `0` : (((addrmap[`5`] >> `24`) &
1123	ROW_MAX_VAL_MASK) + ROW_B11_BASE);
1124	priv->row_shift[`12`] = ((addrmap[`6`] & ROW_MAX_VAL_MASK) ==
1125	ROW_MAX_VAL_MASK) ? `0` : ((addrmap[`6`] &
1126	ROW_MAX_VAL_MASK) + ROW_B12_BASE);
1127	priv->row_shift[`13`] = (((addrmap[`6`] >> `8`) & ROW_MAX_VAL_MASK) ==
1128	ROW_MAX_VAL_MASK) ? `0` : (((addrmap[`6`] >> `8`) &
1129	ROW_MAX_VAL_MASK) + ROW_B13_BASE);
1130	priv->row_shift[`14`] = (((addrmap[`6`] >> `16`) & ROW_MAX_VAL_MASK) ==
1131	ROW_MAX_VAL_MASK) ? `0` : (((addrmap[`6`] >> `16`) &
1132	ROW_MAX_VAL_MASK) + ROW_B14_BASE);
1133	priv->row_shift[`15`] = (((addrmap[`6`] >> `24`) & ROW_MAX_VAL_MASK) ==
1134	ROW_MAX_VAL_MASK) ? `0` : (((addrmap[`6`] >> `24`) &
1135	ROW_MAX_VAL_MASK) + ROW_B15_BASE);
1136	priv->row_shift[`16`] = ((addrmap[`7`] & ROW_MAX_VAL_MASK) ==
1137	ROW_MAX_VAL_MASK) ? `0` : ((addrmap[`7`] &
1138	ROW_MAX_VAL_MASK) + ROW_B16_BASE);
1139	priv->row_shift[`17`] = (((addrmap[`7`] >> `8`) & ROW_MAX_VAL_MASK) ==
1140	ROW_MAX_VAL_MASK) ? `0` : (((addrmap[`7`] >> `8`) &
1141	ROW_MAX_VAL_MASK) + ROW_B17_BASE);
1142	}
1143
1144	static void setup_column_address_map(struct synps_edac_priv priv, u32 addrmap)
1145	{
1146	u32 width, memtype;
1147	int index;
1148
1149	memtype = readl(addr: priv->baseaddr + CTRL_OFST);
1150	width = (memtype & ECC_CTRL_BUSWIDTH_MASK) >> ECC_CTRL_BUSWIDTH_SHIFT;
1151
1152	priv->col_shift[`0`] = `0`;
1153	priv->col_shift[`1`] = `1`;
1154	priv->col_shift[`2`] = (addrmap[`2`] & COL_MAX_VAL_MASK) + COL_B2_BASE;
1155	priv->col_shift[`3`] = ((addrmap[`2`] >> `8`) &
1156	COL_MAX_VAL_MASK) + COL_B3_BASE;
1157	priv->col_shift[`4`] = (((addrmap[`2`] >> `16`) & COL_MAX_VAL_MASK) ==
1158	COL_MAX_VAL_MASK) ? `0` : (((addrmap[`2`] >> `16`) &
1159	COL_MAX_VAL_MASK) + COL_B4_BASE);
1160	priv->col_shift[`5`] = (((addrmap[`2`] >> `24`) & COL_MAX_VAL_MASK) ==
1161	COL_MAX_VAL_MASK) ? `0` : (((addrmap[`2`] >> `24`) &
1162	COL_MAX_VAL_MASK) + COL_B5_BASE);
1163	priv->col_shift[`6`] = ((addrmap[`3`] & COL_MAX_VAL_MASK) ==
1164	COL_MAX_VAL_MASK) ? `0` : ((addrmap[`3`] &
1165	COL_MAX_VAL_MASK) + COL_B6_BASE);
1166	priv->col_shift[`7`] = (((addrmap[`3`] >> `8`) & COL_MAX_VAL_MASK) ==
1167	COL_MAX_VAL_MASK) ? `0` : (((addrmap[`3`] >> `8`) &
1168	COL_MAX_VAL_MASK) + COL_B7_BASE);
1169	priv->col_shift[`8`] = (((addrmap[`3`] >> `16`) & COL_MAX_VAL_MASK) ==
1170	COL_MAX_VAL_MASK) ? `0` : (((addrmap[`3`] >> `16`) &
1171	COL_MAX_VAL_MASK) + COL_B8_BASE);
1172	priv->col_shift[`9`] = (((addrmap[`3`] >> `24`) & COL_MAX_VAL_MASK) ==
1173	COL_MAX_VAL_MASK) ? `0` : (((addrmap[`3`] >> `24`) &
1174	COL_MAX_VAL_MASK) + COL_B9_BASE);
1175	if (width == DDRCTL_EWDTH_64) {
1176	if (memtype & MEM_TYPE_LPDDR3) {
1177	priv->col_shift[`10`] = ((addrmap[`4`] &
1178	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1179	((addrmap[`4`] & COL_MAX_VAL_MASK) +
1180	COL_B10_BASE);
1181	priv->col_shift[`11`] = (((addrmap[`4`] >> `8`) &
1182	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1183	(((addrmap[`4`] >> `8`) & COL_MAX_VAL_MASK) +
1184	COL_B11_BASE);
1185	} else {
1186	priv->col_shift[`11`] = ((addrmap[`4`] &
1187	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1188	((addrmap[`4`] & COL_MAX_VAL_MASK) +
1189	COL_B10_BASE);
1190	priv->col_shift[`13`] = (((addrmap[`4`] >> `8`) &
1191	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1192	(((addrmap[`4`] >> `8`) & COL_MAX_VAL_MASK) +
1193	COL_B11_BASE);
1194	}
1195	} else if (width == DDRCTL_EWDTH_32) {
1196	if (memtype & MEM_TYPE_LPDDR3) {
1197	priv->col_shift[`10`] = (((addrmap[`3`] >> `24`) &
1198	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1199	(((addrmap[`3`] >> `24`) & COL_MAX_VAL_MASK) +
1200	COL_B9_BASE);
1201	priv->col_shift[`11`] = ((addrmap[`4`] &
1202	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1203	((addrmap[`4`] & COL_MAX_VAL_MASK) +
1204	COL_B10_BASE);
1205	} else {
1206	priv->col_shift[`11`] = (((addrmap[`3`] >> `24`) &
1207	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1208	(((addrmap[`3`] >> `24`) & COL_MAX_VAL_MASK) +
1209	COL_B9_BASE);
1210	priv->col_shift[`13`] = ((addrmap[`4`] &
1211	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1212	((addrmap[`4`] & COL_MAX_VAL_MASK) +
1213	COL_B10_BASE);
1214	}
1215	} else {
1216	if (memtype & MEM_TYPE_LPDDR3) {
1217	priv->col_shift[`10`] = (((addrmap[`3`] >> `16`) &
1218	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1219	(((addrmap[`3`] >> `16`) & COL_MAX_VAL_MASK) +
1220	COL_B8_BASE);
1221	priv->col_shift[`11`] = (((addrmap[`3`] >> `24`) &
1222	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1223	(((addrmap[`3`] >> `24`) & COL_MAX_VAL_MASK) +
1224	COL_B9_BASE);
1225	priv->col_shift[`13`] = ((addrmap[`4`] &
1226	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1227	((addrmap[`4`] & COL_MAX_VAL_MASK) +
1228	COL_B10_BASE);
1229	} else {
1230	priv->col_shift[`11`] = (((addrmap[`3`] >> `16`) &
1231	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1232	(((addrmap[`3`] >> `16`) & COL_MAX_VAL_MASK) +
1233	COL_B8_BASE);
1234	priv->col_shift[`13`] = (((addrmap[`3`] >> `24`) &
1235	COL_MAX_VAL_MASK) == COL_MAX_VAL_MASK) ? `0` :
1236	(((addrmap[`3`] >> `24`) & COL_MAX_VAL_MASK) +
1237	COL_B9_BASE);
1238	}
1239	}
1240
1241	if (width) {
1242	for (index = `9`; index > width; index--) {
1243	priv->col_shift[index] = priv->col_shift[index - width];
1244	priv->col_shift[index - width] = `0`;
1245	}
1246	}
1247
1248	}
1249
1250	static void setup_bank_address_map(struct synps_edac_priv priv, u32 addrmap)
1251	{
1252	priv->bank_shift[`0`] = (addrmap[`1`] & BANK_MAX_VAL_MASK) + BANK_B0_BASE;
1253	priv->bank_shift[`1`] = ((addrmap[`1`] >> `8`) &
1254	BANK_MAX_VAL_MASK) + BANK_B1_BASE;
1255	priv->bank_shift[`2`] = (((addrmap[`1`] >> `16`) &
1256	BANK_MAX_VAL_MASK) == BANK_MAX_VAL_MASK) ? `0` :
1257	(((addrmap[`1`] >> `16`) & BANK_MAX_VAL_MASK) +
1258	BANK_B2_BASE);
1259
1260	}
1261
1262	static void setup_bg_address_map(struct synps_edac_priv priv, u32 addrmap)
1263	{
1264	priv->bankgrp_shift[`0`] = (addrmap[`8`] &
1265	BANKGRP_MAX_VAL_MASK) + BANKGRP_B0_BASE;
1266	priv->bankgrp_shift[`1`] = (((addrmap[`8`] >> `8`) & BANKGRP_MAX_VAL_MASK) ==
1267	BANKGRP_MAX_VAL_MASK) ? `0` : (((addrmap[`8`] >> `8`)
1268	& BANKGRP_MAX_VAL_MASK) + BANKGRP_B1_BASE);
1269
1270	}
1271
1272	static void setup_rank_address_map(struct synps_edac_priv priv, u32 addrmap)
1273	{
1274	priv->rank_shift[`0`] = ((addrmap[`0`] & RANK_MAX_VAL_MASK) ==
1275	RANK_MAX_VAL_MASK) ? `0` : ((addrmap[`0`] &
1276	RANK_MAX_VAL_MASK) + RANK_B0_BASE);
1277	}
1278
1279	/**
1280	* setup_address_map - Set Address Map by querying ADDRMAP registers.
1281	* @priv: DDR memory controller private instance data.
1282	*
1283	* Set Address Map by querying ADDRMAP registers.
1284	*
1285	* Return: none.
1286	*/
1287	static void setup_address_map(struct synps_edac_priv *priv)
1288	{
1289	u32 addrmap[`12`];
1290	int index;
1291
1292	for (index = `0`; index < `12`; index++) {
1293	u32 addrmap_offset;
1294
1295	addrmap_offset = ECC_ADDRMAP0_OFFSET + (index * `4`);
1296	addrmap[index] = readl(addr: priv->baseaddr + addrmap_offset);
1297	}
1298
1299	setup_row_address_map(priv, addrmap);
1300
1301	setup_column_address_map(priv, addrmap);
1302
1303	setup_bank_address_map(priv, addrmap);
1304
1305	setup_bg_address_map(priv, addrmap);
1306
1307	setup_rank_address_map(priv, addrmap);
1308	}
1309	#endif /* CONFIG_EDAC_DEBUG */
1310
1311	/**
1312	* mc_probe - Check controller and bind driver.
1313	* @pdev: platform device.
1314	*
1315	* Probe a specific controller instance for binding with the driver.
1316	*
1317	* Return: 0 if the controller instance was successfully bound to the
1318	* driver; otherwise, < 0 on error.
1319	*/
1320	static int mc_probe(struct platform_device *pdev)
1321	{
1322	const struct synps_platform_data *p_data;
1323	struct edac_mc_layer layers[`2`];
1324	struct synps_edac_priv *priv;
1325	struct mem_ctl_info *mci;
1326	void __iomem *baseaddr;
1327	int rc;
1328
1329	baseaddr = devm_platform_ioremap_resource(pdev, index: `0`);
1330	if (IS_ERR(ptr: baseaddr))
1331	return PTR_ERR(ptr: baseaddr);
1332
1333	p_data = of_device_get_match_data(dev: &pdev->dev);
1334	if (!p_data)
1335	return -ENODEV;
1336
1337	if (!p_data->get_ecc_state(baseaddr)) {
1338	edac_printk(KERN_INFO, EDAC_MC, "ECC not enabled\n");
1339	return -ENXIO;
1340	}
1341
1342	layers[`0`].type = EDAC_MC_LAYER_CHIP_SELECT;
1343	layers[`0`].size = SYNPS_EDAC_NR_CSROWS;
1344	layers[`0`].is_virt_csrow = true;
1345	layers[`1`].type = EDAC_MC_LAYER_CHANNEL;
1346	layers[`1`].size = SYNPS_EDAC_NR_CHANS;
1347	layers[`1`].is_virt_csrow = false;
1348
1349	mci = edac_mc_alloc(mc_num: `0`, ARRAY_SIZE(layers), layers,
1350	sz_pvt: sizeof(struct synps_edac_priv));
1351	if (!mci) {
1352	edac_printk(KERN_ERR, EDAC_MC,
1353	"Failed memory allocation for mc instance\n");
1354	return -ENOMEM;
1355	}
1356
1357	priv = mci->pvt_info;
1358	priv->baseaddr = baseaddr;
1359	priv->p_data = p_data;
1360
1361	mc_init(mci, pdev);
1362
1363	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT) {
1364	rc = setup_irq(mci, pdev);
1365	if (rc)
1366	goto free_edac_mc;
1367	}
1368
1369	rc = edac_mc_add_mc(mci);
1370	if (rc) {
1371	edac_printk(KERN_ERR, EDAC_MC,
1372	"Failed to register with EDAC core\n");
1373	goto free_edac_mc;
1374	}
1375
1376	#ifdef CONFIG_EDAC_DEBUG
1377	if (priv->p_data->quirks & DDR_ECC_DATA_POISON_SUPPORT) {
1378	rc = edac_create_sysfs_attributes(mci);
1379	if (rc) {
1380	edac_printk(KERN_ERR, EDAC_MC,
1381	"Failed to create sysfs entries\n");
1382	goto free_edac_mc;
1383	}
1384	}
1385
1386	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT)
1387	setup_address_map(priv);
1388	#endif
1389
1390	/*
1391	* Start capturing the correctable and uncorrectable errors. A write of
1392	* 0 starts the counters.
1393	*/
1394	if (!(priv->p_data->quirks & DDR_ECC_INTR_SUPPORT))
1395	writel(val: `0x0`, addr: baseaddr + ECC_CTRL_OFST);
1396
1397	return rc;
1398
1399	free_edac_mc:
1400	edac_mc_free(mci);
1401
1402	return rc;
1403	}
1404
1405	/**
1406	* mc_remove - Unbind driver from controller.
1407	* @pdev: Platform device.
1408	*
1409	* Return: Unconditionally 0
1410	*/
1411	static void mc_remove(struct platform_device *pdev)
1412	{
1413	struct mem_ctl_info *mci = platform_get_drvdata(pdev);
1414	struct synps_edac_priv *priv = mci->pvt_info;
1415
1416	if (priv->p_data->quirks & DDR_ECC_INTR_SUPPORT)
1417	disable_intr(priv);
1418
1419	#ifdef CONFIG_EDAC_DEBUG
1420	if (priv->p_data->quirks & DDR_ECC_DATA_POISON_SUPPORT)
1421	edac_remove_sysfs_attributes(mci);
1422	#endif
1423
1424	edac_mc_del_mc(dev: &pdev->dev);
1425	edac_mc_free(mci);
1426	}
1427
1428	static struct platform_driver synps_edac_mc_driver = {
1429	.driver = {
1430	.name = "synopsys-edac",
1431	.of_match_table = synps_edac_match,
1432	},
1433	.probe = mc_probe,
1434	.remove_new = mc_remove,
1435	};
1436
1437	module_platform_driver(synps_edac_mc_driver);
1438
1439	MODULE_AUTHOR("Xilinx Inc");
1440	MODULE_DESCRIPTION("Synopsys DDR ECC driver");
1441	MODULE_LICENSE("GPL v2");
1442

source code of linux/drivers/edac/synopsys_edac.c