mc_smp.c source code [linux/arch/arm/mach-sunxi/mc_smp.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/*
3	* Copyright (c) 2018 Chen-Yu Tsai
4	*
5	* Chen-Yu Tsai <wens@csie.org>
6	*
7	* arch/arm/mach-sunxi/mc_smp.c
8	*
9	* Based on Allwinner code, arch/arm/mach-exynos/mcpm-exynos.c, and
10	* arch/arm/mach-hisi/platmcpm.c
11	* Cluster cache enable trampoline code adapted from MCPM framework
12	*/
13
14	#include <linux/arm-cci.h>
15	#include <linux/cpu_pm.h>
16	#include <linux/delay.h>
17	#include <linux/io.h>
18	#include <linux/iopoll.h>
19	#include <linux/irqchip/arm-gic.h>
20	#include <linux/of.h>
21	#include <linux/of_address.h>
22	#include <linux/smp.h>
23
24	#include <asm/cacheflush.h>
25	#include <asm/cp15.h>
26	#include <asm/cputype.h>
27	#include <asm/idmap.h>
28	#include <asm/smp_plat.h>
29	#include <asm/suspend.h>
30
31	#define SUNXI_CPUS_PER_CLUSTER 4
32	#define SUNXI_NR_CLUSTERS 2
33
34	#define POLL_USEC 100
35	#define TIMEOUT_USEC 100000
36
37	#define CPUCFG_CX_CTRL_REG0(c) (0x10 * (c))
38	#define CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE(n) BIT(n)
39	#define CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE_ALL 0xf
40	#define CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A7 BIT(4)
41	#define CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A15 BIT(0)
42	#define CPUCFG_CX_CTRL_REG1(c) (0x10 * (c) + 0x4)
43	#define CPUCFG_CX_CTRL_REG1_ACINACTM BIT(0)
44	#define CPUCFG_CX_STATUS(c) (0x30 + 0x4 * (c))
45	#define CPUCFG_CX_STATUS_STANDBYWFI(n) BIT(16 + (n))
46	#define CPUCFG_CX_STATUS_STANDBYWFIL2 BIT(0)
47	#define CPUCFG_CX_RST_CTRL(c) (0x80 + 0x4 * (c))
48	#define CPUCFG_CX_RST_CTRL_DBG_SOC_RST BIT(24)
49	#define CPUCFG_CX_RST_CTRL_ETM_RST(n) BIT(20 + (n))
50	#define CPUCFG_CX_RST_CTRL_ETM_RST_ALL (0xf << 20)
51	#define CPUCFG_CX_RST_CTRL_DBG_RST(n) BIT(16 + (n))
52	#define CPUCFG_CX_RST_CTRL_DBG_RST_ALL (0xf << 16)
53	#define CPUCFG_CX_RST_CTRL_H_RST BIT(12)
54	#define CPUCFG_CX_RST_CTRL_L2_RST BIT(8)
55	#define CPUCFG_CX_RST_CTRL_CX_RST(n) BIT(4 + (n))
56	#define CPUCFG_CX_RST_CTRL_CORE_RST(n) BIT(n)
57	#define CPUCFG_CX_RST_CTRL_CORE_RST_ALL (0xf << 0)
58
59	#define PRCM_CPU_PO_RST_CTRL(c) (0x4 + 0x4 * (c))
60	#define PRCM_CPU_PO_RST_CTRL_CORE(n) BIT(n)
61	#define PRCM_CPU_PO_RST_CTRL_CORE_ALL 0xf
62	#define PRCM_PWROFF_GATING_REG(c) (0x100 + 0x4 * (c))
63	/ The power off register for clusters are different from a80 and a83t /
64	#define PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I BIT(0)
65	#define PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I BIT(4)
66	#define PRCM_PWROFF_GATING_REG_CORE(n) BIT(n)
67	#define PRCM_PWR_SWITCH_REG(c, cpu) (0x140 + 0x10 * (c) + 0x4 * (cpu))
68	#define PRCM_CPU_SOFT_ENTRY_REG 0x164
69
70	/ R_CPUCFG registers, specific to sun8i-a83t /
71	#define R_CPUCFG_CLUSTER_PO_RST_CTRL(c) (0x30 + (c) * 0x4)
72	#define R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(n) BIT(n)
73	#define R_CPUCFG_CPU_SOFT_ENTRY_REG 0x01a4
74
75	#define CPU0_SUPPORT_HOTPLUG_MAGIC0 0xFA50392F
76	#define CPU0_SUPPORT_HOTPLUG_MAGIC1 0x790DCA3A
77
78	static void __iomem *cpucfg_base;
79	static void __iomem *prcm_base;
80	static void __iomem *sram_b_smp_base;
81	static void __iomem *r_cpucfg_base;
82
83	extern void sunxi_mc_smp_secondary_startup(void);
84	extern void sunxi_mc_smp_resume(void);
85	static bool is_a83t;
86
87	static bool sunxi_core_is_cortex_a15(unsigned int core, unsigned int cluster)
88	{
89	struct device_node *node;
90	int cpu = cluster * SUNXI_CPUS_PER_CLUSTER + core;
91	bool is_compatible;
92
93	node = of_cpu_device_node_get(cpu);
94
95	/ In case of_cpu_device_node_get fails /
96	if (!node)
97	node = of_get_cpu_node(cpu, NULL);
98
99	if (!node) {
100	/*
101	* There's no point in returning an error, since we
102	* would be mid way in a core or cluster power sequence.
103	*/
104	pr_err("%s: Couldn't get CPU cluster %u core %u device node\n",
105	__func__, cluster, core);
106
107	return false;
108	}
109
110	is_compatible = of_device_is_compatible(device: node, "arm,cortex-a15");
111	of_node_put(node);
112	return is_compatible;
113	}
114
115	static int sunxi_cpu_power_switch_set(unsigned int cpu, unsigned int cluster,
116	bool enable)
117	{
118	u32 reg;
119
120	/ control sequence from Allwinner A80 user manual v1.2 PRCM section /
121	reg = readl(addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
122	if (enable) {
123	if (reg == `0x00`) {
124	pr_debug("power clamp for cluster %u cpu %u already open\n",
125	cluster, cpu);
126	return `0`;
127	}
128
129	writel(val: `0xff`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
130	udelay(`10`);
131	writel(val: `0xfe`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
132	udelay(`10`);
133	writel(val: `0xf8`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
134	udelay(`10`);
135	writel(val: `0xf0`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
136	udelay(`10`);
137	writel(val: `0x00`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
138	udelay(`10`);
139	} else {
140	writel(val: `0xff`, addr: prcm_base + PRCM_PWR_SWITCH_REG(cluster, cpu));
141	udelay(`10`);
142	}
143
144	return `0`;
145	}
146
147	static void sunxi_cpu0_hotplug_support_set(bool enable)
148	{
149	if (enable) {
150	writel(CPU0_SUPPORT_HOTPLUG_MAGIC0, addr: sram_b_smp_base);
151	writel(CPU0_SUPPORT_HOTPLUG_MAGIC1, addr: sram_b_smp_base + `0x4`);
152	} else {
153	writel(val: `0x0`, addr: sram_b_smp_base);
154	writel(val: `0x0`, addr: sram_b_smp_base + `0x4`);
155	}
156	}
157
158	static int sunxi_cpu_powerup(unsigned int cpu, unsigned int cluster)
159	{
160	u32 reg;
161
162	pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu);
163	if (cpu >= SUNXI_CPUS_PER_CLUSTER \|\| cluster >= SUNXI_NR_CLUSTERS)
164	return -EINVAL;
165
166	/ Set hotplug support magic flags for cpu0 /
167	if (cluster == `0` && cpu == `0`)
168	sunxi_cpu0_hotplug_support_set(enable: true);
169
170	/ assert processor power-on reset /
171	reg = readl(addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
172	reg &= ~PRCM_CPU_PO_RST_CTRL_CORE(cpu);
173	writel(val: reg, addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
174
175	if (is_a83t) {
176	/ assert cpu power-on reset /
177	reg = readl(addr: r_cpucfg_base +
178	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
179	reg &= ~(R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(cpu));
180	writel(val: reg, addr: r_cpucfg_base +
181	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
182	udelay(`10`);
183	}
184
185	/ Cortex-A7: hold L1 reset disable signal low /
186	if (!sunxi_core_is_cortex_a15(core: cpu, cluster)) {
187	reg = readl(addr: cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster));
188	reg &= ~CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE(cpu);
189	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster));
190	}
191
192	/ assert processor related resets /
193	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
194	reg &= ~CPUCFG_CX_RST_CTRL_DBG_RST(cpu);
195
196	/*
197	* Allwinner code also asserts resets for NEON on A15. According
198	* to ARM manuals, asserting power-on reset is sufficient.
199	*/
200	if (!sunxi_core_is_cortex_a15(core: cpu, cluster))
201	reg &= ~CPUCFG_CX_RST_CTRL_ETM_RST(cpu);
202
203	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
204
205	/ open power switch /
206	sunxi_cpu_power_switch_set(cpu, cluster, enable: true);
207
208	/ Handle A83T bit swap /
209	if (is_a83t) {
210	if (cpu == `0`)
211	cpu = `4`;
212	}
213
214	/ clear processor power gate /
215	reg = readl(addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
216	reg &= ~PRCM_PWROFF_GATING_REG_CORE(cpu);
217	writel(val: reg, addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
218	udelay(`20`);
219
220	/ Handle A83T bit swap /
221	if (is_a83t) {
222	if (cpu == `4`)
223	cpu = `0`;
224	}
225
226	/ de-assert processor power-on reset /
227	reg = readl(addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
228	reg \|= PRCM_CPU_PO_RST_CTRL_CORE(cpu);
229	writel(val: reg, addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
230
231	if (is_a83t) {
232	reg = readl(addr: r_cpucfg_base +
233	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
234	reg \|= R_CPUCFG_CLUSTER_PO_RST_CTRL_CORE(cpu);
235	writel(val: reg, addr: r_cpucfg_base +
236	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
237	udelay(`10`);
238	}
239
240	/ de-assert all processor resets /
241	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
242	reg \|= CPUCFG_CX_RST_CTRL_DBG_RST(cpu);
243	reg \|= CPUCFG_CX_RST_CTRL_CORE_RST(cpu);
244	if (!sunxi_core_is_cortex_a15(core: cpu, cluster))
245	reg \|= CPUCFG_CX_RST_CTRL_ETM_RST(cpu);
246	else
247	reg \|= CPUCFG_CX_RST_CTRL_CX_RST(cpu); / NEON /
248	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
249
250	return `0`;
251	}
252
253	static int sunxi_cluster_powerup(unsigned int cluster)
254	{
255	u32 reg;
256
257	pr_debug("%s: cluster %u\n", __func__, cluster);
258	if (cluster >= SUNXI_NR_CLUSTERS)
259	return -EINVAL;
260
261	/ For A83T, assert cluster cores resets /
262	if (is_a83t) {
263	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
264	reg &= ~CPUCFG_CX_RST_CTRL_CORE_RST_ALL; / Core Reset /
265	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
266	udelay(`10`);
267	}
268
269	/ assert ACINACTM /
270	reg = readl(addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
271	reg \|= CPUCFG_CX_CTRL_REG1_ACINACTM;
272	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
273
274	/ assert cluster processor power-on resets /
275	reg = readl(addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
276	reg &= ~PRCM_CPU_PO_RST_CTRL_CORE_ALL;
277	writel(val: reg, addr: prcm_base + PRCM_CPU_PO_RST_CTRL(cluster));
278
279	/ assert cluster cores resets /
280	if (is_a83t) {
281	reg = readl(addr: r_cpucfg_base +
282	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
283	reg &= ~CPUCFG_CX_RST_CTRL_CORE_RST_ALL;
284	writel(val: reg, addr: r_cpucfg_base +
285	R_CPUCFG_CLUSTER_PO_RST_CTRL(cluster));
286	udelay(`10`);
287	}
288
289	/ assert cluster resets /
290	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
291	reg &= ~CPUCFG_CX_RST_CTRL_DBG_SOC_RST;
292	reg &= ~CPUCFG_CX_RST_CTRL_DBG_RST_ALL;
293	reg &= ~CPUCFG_CX_RST_CTRL_H_RST;
294	reg &= ~CPUCFG_CX_RST_CTRL_L2_RST;
295
296	/*
297	* Allwinner code also asserts resets for NEON on A15. According
298	* to ARM manuals, asserting power-on reset is sufficient.
299	*/
300	if (!sunxi_core_is_cortex_a15(core: `0`, cluster))
301	reg &= ~CPUCFG_CX_RST_CTRL_ETM_RST_ALL;
302
303	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
304
305	/ hold L1/L2 reset disable signals low /
306	reg = readl(addr: cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster));
307	if (sunxi_core_is_cortex_a15(core: `0`, cluster)) {
308	/ Cortex-A15: hold L2RSTDISABLE low /
309	reg &= ~CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A15;
310	} else {
311	/ Cortex-A7: hold L1RSTDISABLE and L2RSTDISABLE low /
312	reg &= ~CPUCFG_CX_CTRL_REG0_L1_RST_DISABLE_ALL;
313	reg &= ~CPUCFG_CX_CTRL_REG0_L2_RST_DISABLE_A7;
314	}
315	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_CTRL_REG0(cluster));
316
317	/ clear cluster power gate /
318	reg = readl(addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
319	if (is_a83t)
320	reg &= ~PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I;
321	else
322	reg &= ~PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I;
323	writel(val: reg, addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
324	udelay(`20`);
325
326	/ de-assert cluster resets /
327	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
328	reg \|= CPUCFG_CX_RST_CTRL_DBG_SOC_RST;
329	reg \|= CPUCFG_CX_RST_CTRL_H_RST;
330	reg \|= CPUCFG_CX_RST_CTRL_L2_RST;
331	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
332
333	/ de-assert ACINACTM /
334	reg = readl(addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
335	reg &= ~CPUCFG_CX_CTRL_REG1_ACINACTM;
336	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
337
338	return `0`;
339	}
340
341	/*
342	* This bit is shared between the initial nocache_trampoline call to
343	* enable CCI-400 and proper cluster cache disable before power down.
344	*/
345	static void sunxi_cluster_cache_disable_without_axi(void)
346	{
347	if (read_cpuid_part() == ARM_CPU_PART_CORTEX_A15) {
348	/*
349	* On the Cortex-A15 we need to disable
350	* L2 prefetching before flushing the cache.
351	*/
352	asm volatile(
353	"mcr p15, 1, %0, c15, c0, 3\n"
354	"isb\n"
355	"dsb"
356	: : "r" (`0x400`));
357	}
358
359	/ Flush all cache levels for this cluster. /
360	v7_exit_coherency_flush(all);
361
362	/*
363	* Disable cluster-level coherency by masking
364	* incoming snoops and DVM messages:
365	*/
366	cci_disable_port_by_cpu(mpidr: read_cpuid_mpidr());
367	}
368
369	static int sunxi_mc_smp_cpu_table[SUNXI_NR_CLUSTERS][SUNXI_CPUS_PER_CLUSTER];
370	int sunxi_mc_smp_first_comer;
371
372	static DEFINE_SPINLOCK(boot_lock);
373
374	static bool sunxi_mc_smp_cluster_is_down(unsigned int cluster)
375	{
376	int i;
377
378	for (i = `0`; i < SUNXI_CPUS_PER_CLUSTER; i++)
379	if (sunxi_mc_smp_cpu_table[cluster][i])
380	return false;
381	return true;
382	}
383
384	static void sunxi_mc_smp_secondary_init(unsigned int cpu)
385	{
386	/ Clear hotplug support magic flags for cpu0 /
387	if (cpu == `0`)
388	sunxi_cpu0_hotplug_support_set(enable: false);
389	}
390
391	static int sunxi_mc_smp_boot_secondary(unsigned int l_cpu, struct task_struct *idle)
392	{
393	unsigned int mpidr, cpu, cluster;
394
395	mpidr = cpu_logical_map(l_cpu);
396	cpu = MPIDR_AFFINITY_LEVEL(mpidr, `0`);
397	cluster = MPIDR_AFFINITY_LEVEL(mpidr, `1`);
398
399	if (!cpucfg_base)
400	return -ENODEV;
401	if (cluster >= SUNXI_NR_CLUSTERS \|\| cpu >= SUNXI_CPUS_PER_CLUSTER)
402	return -EINVAL;
403
404	spin_lock_irq(lock: &boot_lock);
405
406	if (sunxi_mc_smp_cpu_table[cluster][cpu])
407	goto out;
408
409	if (sunxi_mc_smp_cluster_is_down(cluster)) {
410	sunxi_mc_smp_first_comer = true;
411	sunxi_cluster_powerup(cluster);
412	} else {
413	sunxi_mc_smp_first_comer = false;
414	}
415
416	/ This is read by incoming CPUs with their cache and MMU disabled /
417	sync_cache_w(&sunxi_mc_smp_first_comer);
418	sunxi_cpu_powerup(cpu, cluster);
419
420	out:
421	sunxi_mc_smp_cpu_table[cluster][cpu]++;
422	spin_unlock_irq(lock: &boot_lock);
423
424	return `0`;
425	}
426
427	#ifdef CONFIG_HOTPLUG_CPU
428	static void sunxi_cluster_cache_disable(void)
429	{
430	unsigned int cluster = MPIDR_AFFINITY_LEVEL(read_cpuid_mpidr(), `1`);
431	u32 reg;
432
433	pr_debug("%s: cluster %u\n", __func__, cluster);
434
435	sunxi_cluster_cache_disable_without_axi();
436
437	/ last man standing, assert ACINACTM /
438	reg = readl(addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
439	reg \|= CPUCFG_CX_CTRL_REG1_ACINACTM;
440	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_CTRL_REG1(cluster));
441	}
442
443	static void sunxi_mc_smp_cpu_die(unsigned int l_cpu)
444	{
445	unsigned int mpidr, cpu, cluster;
446	bool last_man;
447
448	mpidr = cpu_logical_map(l_cpu);
449	cpu = MPIDR_AFFINITY_LEVEL(mpidr, `0`);
450	cluster = MPIDR_AFFINITY_LEVEL(mpidr, `1`);
451	pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu);
452
453	spin_lock(lock: &boot_lock);
454	sunxi_mc_smp_cpu_table[cluster][cpu]--;
455	if (sunxi_mc_smp_cpu_table[cluster][cpu] == `1`) {
456	/ A power_up request went ahead of us. /
457	pr_debug("%s: aborting due to a power up request\n",
458	__func__);
459	spin_unlock(lock: &boot_lock);
460	return;
461	} else if (sunxi_mc_smp_cpu_table[cluster][cpu] > `1`) {
462	pr_err("Cluster %d CPU%d boots multiple times\n",
463	cluster, cpu);
464	BUG();
465	}
466
467	last_man = sunxi_mc_smp_cluster_is_down(cluster);
468	spin_unlock(lock: &boot_lock);
469
470	gic_cpu_if_down(gic_nr: `0`);
471	if (last_man)
472	sunxi_cluster_cache_disable();
473	else
474	v7_exit_coherency_flush(louis);
475
476	for (;;)
477	wfi();
478	}
479
480	static int sunxi_cpu_powerdown(unsigned int cpu, unsigned int cluster)
481	{
482	u32 reg;
483	int gating_bit = cpu;
484
485	pr_debug("%s: cluster %u cpu %u\n", __func__, cluster, cpu);
486	if (cpu >= SUNXI_CPUS_PER_CLUSTER \|\| cluster >= SUNXI_NR_CLUSTERS)
487	return -EINVAL;
488
489	if (is_a83t && cpu == `0`)
490	gating_bit = `4`;
491
492	/ gate processor power /
493	reg = readl(addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
494	reg \|= PRCM_PWROFF_GATING_REG_CORE(gating_bit);
495	writel(val: reg, addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
496	udelay(`20`);
497
498	/ close power switch /
499	sunxi_cpu_power_switch_set(cpu, cluster, enable: false);
500
501	return `0`;
502	}
503
504	static int sunxi_cluster_powerdown(unsigned int cluster)
505	{
506	u32 reg;
507
508	pr_debug("%s: cluster %u\n", __func__, cluster);
509	if (cluster >= SUNXI_NR_CLUSTERS)
510	return -EINVAL;
511
512	/ assert cluster resets or system will hang /
513	pr_debug("%s: assert cluster reset\n", __func__);
514	reg = readl(addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
515	reg &= ~CPUCFG_CX_RST_CTRL_DBG_SOC_RST;
516	reg &= ~CPUCFG_CX_RST_CTRL_H_RST;
517	reg &= ~CPUCFG_CX_RST_CTRL_L2_RST;
518	writel(val: reg, addr: cpucfg_base + CPUCFG_CX_RST_CTRL(cluster));
519
520	/ gate cluster power /
521	pr_debug("%s: gate cluster power\n", __func__);
522	reg = readl(addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
523	if (is_a83t)
524	reg \|= PRCM_PWROFF_GATING_REG_CLUSTER_SUN8I;
525	else
526	reg \|= PRCM_PWROFF_GATING_REG_CLUSTER_SUN9I;
527	writel(val: reg, addr: prcm_base + PRCM_PWROFF_GATING_REG(cluster));
528	udelay(`20`);
529
530	return `0`;
531	}
532
533	static int sunxi_mc_smp_cpu_kill(unsigned int l_cpu)
534	{
535	unsigned int mpidr, cpu, cluster;
536	unsigned int tries, count;
537	int ret = `0`;
538	u32 reg;
539
540	mpidr = cpu_logical_map(l_cpu);
541	cpu = MPIDR_AFFINITY_LEVEL(mpidr, `0`);
542	cluster = MPIDR_AFFINITY_LEVEL(mpidr, `1`);
543
544	/ This should never happen /
545	if (WARN_ON(cluster >= SUNXI_NR_CLUSTERS \|\|
546	cpu >= SUNXI_CPUS_PER_CLUSTER))
547	return `0`;
548
549	/ wait for CPU core to die and enter WFI /
550	count = TIMEOUT_USEC / POLL_USEC;
551	spin_lock_irq(lock: &boot_lock);
552	for (tries = `0`; tries < count; tries++) {
553	spin_unlock_irq(lock: &boot_lock);
554	usleep_range(POLL_USEC / `2`, POLL_USEC);
555	spin_lock_irq(lock: &boot_lock);
556
557	/*
558	* If the user turns off a bunch of cores at the same
559	* time, the kernel might call cpu_kill before some of
560	* them are ready. This is because boot_lock serializes
561	* both cpu_die and cpu_kill callbacks. Either one could
562	* run first. We should wait for cpu_die to complete.
563	*/
564	if (sunxi_mc_smp_cpu_table[cluster][cpu])
565	continue;
566
567	reg = readl(addr: cpucfg_base + CPUCFG_CX_STATUS(cluster));
568	if (reg & CPUCFG_CX_STATUS_STANDBYWFI(cpu))
569	break;
570	}
571
572	if (tries >= count) {
573	ret = ETIMEDOUT;
574	goto out;
575	}
576
577	/ power down CPU core /
578	sunxi_cpu_powerdown(cpu, cluster);
579
580	if (!sunxi_mc_smp_cluster_is_down(cluster))
581	goto out;
582
583	/ wait for cluster L2 WFI /
584	ret = readl_poll_timeout(cpucfg_base + CPUCFG_CX_STATUS(cluster), reg,
585	reg & CPUCFG_CX_STATUS_STANDBYWFIL2,
586	POLL_USEC, TIMEOUT_USEC);
587	if (ret) {
588	/*
589	* Ignore timeout on the cluster. Leaving the cluster on
590	* will not affect system execution, just use a bit more
591	* power. But returning an error here will only confuse
592	* the user as the CPU has already been shutdown.
593	*/
594	ret = `0`;
595	goto out;
596	}
597
598	/ Power down cluster /
599	sunxi_cluster_powerdown(cluster);
600
601	out:
602	spin_unlock_irq(lock: &boot_lock);
603	pr_debug("%s: cluster %u cpu %u powerdown: %d\n",
604	__func__, cluster, cpu, ret);
605	return !ret;
606	}
607
608	static bool sunxi_mc_smp_cpu_can_disable(unsigned int cpu)
609	{
610	/ CPU0 hotplug not handled for sun8i-a83t /
611	if (is_a83t)
612	if (cpu == `0`)
613	return false;
614	return true;
615	}
616	#endif
617
618	static const struct smp_operations sunxi_mc_smp_smp_ops __initconst = {
619	.smp_secondary_init = sunxi_mc_smp_secondary_init,
620	.smp_boot_secondary = sunxi_mc_smp_boot_secondary,
621	#ifdef CONFIG_HOTPLUG_CPU
622	.cpu_die = sunxi_mc_smp_cpu_die,
623	.cpu_kill = sunxi_mc_smp_cpu_kill,
624	.cpu_can_disable = sunxi_mc_smp_cpu_can_disable,
625	#endif
626	};
627
628	static bool __init sunxi_mc_smp_cpu_table_init(void)
629	{
630	unsigned int mpidr, cpu, cluster;
631
632	mpidr = read_cpuid_mpidr();
633	cpu = MPIDR_AFFINITY_LEVEL(mpidr, `0`);
634	cluster = MPIDR_AFFINITY_LEVEL(mpidr, `1`);
635
636	if (cluster >= SUNXI_NR_CLUSTERS \|\| cpu >= SUNXI_CPUS_PER_CLUSTER) {
637	pr_err("%s: boot CPU is out of bounds!\n", __func__);
638	return false;
639	}
640	sunxi_mc_smp_cpu_table[cluster][cpu] = `1`;
641	return true;
642	}
643
644	/*
645	* Adapted from arch/arm/common/mc_smp_entry.c
646	*
647	* We need the trampoline code to enable CCI-400 on the first cluster
648	*/
649	typedef typeof(cpu_reset) phys_reset_t;
650
651	static int __init nocache_trampoline(unsigned long __unused)
652	{
653	phys_reset_t phys_reset;
654
655	setup_mm_for_reboot();
656	sunxi_cluster_cache_disable_without_axi();
657
658	phys_reset = (phys_reset_t)(unsigned long)__pa_symbol(cpu_reset);
659	phys_reset(__pa_symbol(sunxi_mc_smp_resume), false);
660	BUG();
661	}
662
663	static int __init sunxi_mc_smp_loopback(void)
664	{
665	int ret;
666
667	/*
668	* We're going to soft-restart the current CPU through the
669	* low-level MCPM code by leveraging the suspend/resume
670	* infrastructure. Let's play it safe by using cpu_pm_enter()
671	* in case the CPU init code path resets the VFP or similar.
672	*/
673	sunxi_mc_smp_first_comer = true;
674	local_irq_disable();
675	local_fiq_disable();
676	ret = cpu_pm_enter();
677	if (!ret) {
678	ret = cpu_suspend(`0`, nocache_trampoline);
679	cpu_pm_exit();
680	}
681	local_fiq_enable();
682	local_irq_enable();
683	sunxi_mc_smp_first_comer = false;
684
685	return ret;
686	}
687
688	/*
689	* This holds any device nodes that we requested resources for,
690	* so that we may easily release resources in the error path.
691	*/
692	struct sunxi_mc_smp_nodes {
693	struct device_node *prcm_node;
694	struct device_node *cpucfg_node;
695	struct device_node *sram_node;
696	struct device_node *r_cpucfg_node;
697	};
698
699	/ This structure holds SoC-specific bits tied to an enable-method string. /
700	struct sunxi_mc_smp_data {
701	const char *enable_method;
702	int (get_smp_nodes)(struct* sunxi_mc_smp_nodes *nodes);
703	bool is_a83t;
704	};
705
706	static void __init sunxi_mc_smp_put_nodes(struct sunxi_mc_smp_nodes *nodes)
707	{
708	of_node_put(node: nodes->prcm_node);
709	of_node_put(node: nodes->cpucfg_node);
710	of_node_put(node: nodes->sram_node);
711	of_node_put(node: nodes->r_cpucfg_node);
712	memset(nodes, `0`, sizeof(*nodes));
713	}
714
715	static int __init sun9i_a80_get_smp_nodes(struct sunxi_mc_smp_nodes *nodes)
716	{
717	nodes->prcm_node = of_find_compatible_node(NULL, NULL,
718	compat: "allwinner,sun9i-a80-prcm");
719	if (!nodes->prcm_node) {
720	pr_err("%s: PRCM not available\n", __func__);
721	return -ENODEV;
722	}
723
724	nodes->cpucfg_node = of_find_compatible_node(NULL, NULL,
725	compat: "allwinner,sun9i-a80-cpucfg");
726	if (!nodes->cpucfg_node) {
727	pr_err("%s: CPUCFG not available\n", __func__);
728	return -ENODEV;
729	}
730
731	nodes->sram_node = of_find_compatible_node(NULL, NULL,
732	compat: "allwinner,sun9i-a80-smp-sram");
733	if (!nodes->sram_node) {
734	pr_err("%s: Secure SRAM not available\n", __func__);
735	return -ENODEV;
736	}
737
738	return `0`;
739	}
740
741	static int __init sun8i_a83t_get_smp_nodes(struct sunxi_mc_smp_nodes *nodes)
742	{
743	nodes->prcm_node = of_find_compatible_node(NULL, NULL,
744	compat: "allwinner,sun8i-a83t-r-ccu");
745	if (!nodes->prcm_node) {
746	pr_err("%s: PRCM not available\n", __func__);
747	return -ENODEV;
748	}
749
750	nodes->cpucfg_node = of_find_compatible_node(NULL, NULL,
751	compat: "allwinner,sun8i-a83t-cpucfg");
752	if (!nodes->cpucfg_node) {
753	pr_err("%s: CPUCFG not available\n", __func__);
754	return -ENODEV;
755	}
756
757	nodes->r_cpucfg_node = of_find_compatible_node(NULL, NULL,
758	compat: "allwinner,sun8i-a83t-r-cpucfg");
759	if (!nodes->r_cpucfg_node) {
760	pr_err("%s: RCPUCFG not available\n", __func__);
761	return -ENODEV;
762	}
763
764	return `0`;
765	}
766
767	static const struct sunxi_mc_smp_data sunxi_mc_smp_data[] __initconst = {
768	{
769	.enable_method = "allwinner,sun9i-a80-smp",
770	.get_smp_nodes = sun9i_a80_get_smp_nodes,
771	},
772	{
773	.enable_method = "allwinner,sun8i-a83t-smp",
774	.get_smp_nodes = sun8i_a83t_get_smp_nodes,
775	.is_a83t = true,
776	},
777	};
778
779	static int __init sunxi_mc_smp_init(void)
780	{
781	struct sunxi_mc_smp_nodes nodes = { `0` };
782	struct device_node *node;
783	struct resource res;
784	void __iomem *addr;
785	int i, ret;
786
787	/*
788	* Don't bother checking the "cpus" node, as an enable-method
789	* property in that node is undocumented.
790	*/
791	node = of_cpu_device_node_get(cpu: `0`);
792	if (!node)
793	return -ENODEV;
794
795	/*
796	* We can't actually use the enable-method magic in the kernel.
797	* Our loopback / trampoline code uses the CPU suspend framework,
798	* which requires the identity mapping be available. It would not
799	* yet be available if we used the .init_cpus or .prepare_cpus
800	* callbacks in smp_operations, which we would use if we were to
801	* use CPU_METHOD_OF_DECLARE
802	*/
803	for (i = `0`; i < ARRAY_SIZE(sunxi_mc_smp_data); i++) {
804	ret = of_property_match_string(np: node, propname: "enable-method",
805	string: sunxi_mc_smp_data[i].enable_method);
806	if (!ret)
807	break;
808	}
809
810	is_a83t = sunxi_mc_smp_data[i].is_a83t;
811
812	of_node_put(node);
813	if (ret)
814	return -ENODEV;
815
816	if (!sunxi_mc_smp_cpu_table_init())
817	return -EINVAL;
818
819	if (!cci_probed()) {
820	pr_err("%s: CCI-400 not available\n", __func__);
821	return -ENODEV;
822	}
823
824	/ Get needed device tree nodes /
825	ret = sunxi_mc_smp_data[i].get_smp_nodes(&nodes);
826	if (ret)
827	goto err_put_nodes;
828
829	/*
830	* Unfortunately we can not request the I/O region for the PRCM.
831	* It is shared with the PRCM clock.
832	*/
833	prcm_base = of_iomap(node: nodes.prcm_node, index: `0`);
834	if (!prcm_base) {
835	pr_err("%s: failed to map PRCM registers\n", __func__);
836	ret = -ENOMEM;
837	goto err_put_nodes;
838	}
839
840	cpucfg_base = of_io_request_and_map(device: nodes.cpucfg_node, index: `0`,
841	name: "sunxi-mc-smp");
842	if (IS_ERR(ptr: cpucfg_base)) {
843	ret = PTR_ERR(ptr: cpucfg_base);
844	pr_err("%s: failed to map CPUCFG registers: %d\n",
845	__func__, ret);
846	goto err_unmap_prcm;
847	}
848
849	if (is_a83t) {
850	r_cpucfg_base = of_io_request_and_map(device: nodes.r_cpucfg_node,
851	index: `0`, name: "sunxi-mc-smp");
852	if (IS_ERR(ptr: r_cpucfg_base)) {
853	ret = PTR_ERR(ptr: r_cpucfg_base);
854	pr_err("%s: failed to map R-CPUCFG registers\n",
855	__func__);
856	goto err_unmap_release_cpucfg;
857	}
858	} else {
859	sram_b_smp_base = of_io_request_and_map(device: nodes.sram_node, index: `0`,
860	name: "sunxi-mc-smp");
861	if (IS_ERR(ptr: sram_b_smp_base)) {
862	ret = PTR_ERR(ptr: sram_b_smp_base);
863	pr_err("%s: failed to map secure SRAM\n", __func__);
864	goto err_unmap_release_cpucfg;
865	}
866	}
867
868	/ Configure CCI-400 for boot cluster /
869	ret = sunxi_mc_smp_loopback();
870	if (ret) {
871	pr_err("%s: failed to configure boot cluster: %d\n",
872	__func__, ret);
873	goto err_unmap_release_sram_rcpucfg;
874	}
875
876	/ We don't need the device nodes anymore /
877	sunxi_mc_smp_put_nodes(nodes: &nodes);
878
879	/ Set the hardware entry point address /
880	if (is_a83t)
881	addr = r_cpucfg_base + R_CPUCFG_CPU_SOFT_ENTRY_REG;
882	else
883	addr = prcm_base + PRCM_CPU_SOFT_ENTRY_REG;
884	writel(__pa_symbol(sunxi_mc_smp_secondary_startup), addr);
885
886	/ Actually enable multi cluster SMP /
887	smp_set_ops(&sunxi_mc_smp_smp_ops);
888
889	pr_info("sunxi multi cluster SMP support installed\n");
890
891	return `0`;
892
893	err_unmap_release_sram_rcpucfg:
894	if (is_a83t) {
895	iounmap(addr: r_cpucfg_base);
896	of_address_to_resource(dev: nodes.r_cpucfg_node, index: `0`, r: &res);
897	} else {
898	iounmap(addr: sram_b_smp_base);
899	of_address_to_resource(dev: nodes.sram_node, index: `0`, r: &res);
900	}
901	release_mem_region(res.start, resource_size(&res));
902	err_unmap_release_cpucfg:
903	iounmap(addr: cpucfg_base);
904	of_address_to_resource(dev: nodes.cpucfg_node, index: `0`, r: &res);
905	release_mem_region(res.start, resource_size(&res));
906	err_unmap_prcm:
907	iounmap(addr: prcm_base);
908	err_put_nodes:
909	sunxi_mc_smp_put_nodes(nodes: &nodes);
910	return ret;
911	}
912
913	early_initcall(sunxi_mc_smp_init);
914

source code of linux/arch/arm/mach-sunxi/mc_smp.c