xref: /linux/drivers/clk/ingenic/x1000-cgu.c (revision 8a922b7728a93d837954315c98b84f6b78de0c4f)
1 // SPDX-License-Identifier: GPL-2.0
2 /*
3  * X1000 SoC CGU driver
4  * Copyright (c) 2019 周琰杰 (Zhou Yanjie) <zhouyanjie@wanyeetech.com>
5  */
6 
7 #include <linux/clk-provider.h>
8 #include <linux/delay.h>
9 #include <linux/io.h>
10 #include <linux/of.h>
11 #include <linux/rational.h>
12 
13 #include <dt-bindings/clock/ingenic,x1000-cgu.h>
14 
15 #include "cgu.h"
16 #include "pm.h"
17 
18 /* CGU register offsets */
19 #define CGU_REG_CPCCR		0x00
20 #define CGU_REG_APLL		0x10
21 #define CGU_REG_MPLL		0x14
22 #define CGU_REG_CLKGR		0x20
23 #define CGU_REG_OPCR		0x24
24 #define CGU_REG_DDRCDR		0x2c
25 #define CGU_REG_USBPCR		0x3c
26 #define CGU_REG_USBPCR1		0x48
27 #define CGU_REG_USBCDR		0x50
28 #define CGU_REG_MACCDR		0x54
29 #define CGU_REG_I2SCDR		0x60
30 #define CGU_REG_LPCDR		0x64
31 #define CGU_REG_MSC0CDR		0x68
32 #define CGU_REG_I2SCDR1		0x70
33 #define CGU_REG_SSICDR		0x74
34 #define CGU_REG_CIMCDR		0x7c
35 #define CGU_REG_PCMCDR		0x84
36 #define CGU_REG_MSC1CDR		0xa4
37 #define CGU_REG_CMP_INTR	0xb0
38 #define CGU_REG_CMP_INTRE	0xb4
39 #define CGU_REG_DRCG		0xd0
40 #define CGU_REG_CPCSR		0xd4
41 #define CGU_REG_PCMCDR1		0xe0
42 #define CGU_REG_MACPHYC		0xe8
43 
44 /* bits within the OPCR register */
45 #define OPCR_SPENDN0		BIT(7)
46 #define OPCR_SPENDN1		BIT(6)
47 
48 /* bits within the USBPCR register */
49 #define USBPCR_SIDDQ		BIT(21)
50 #define USBPCR_OTG_DISABLE	BIT(20)
51 
52 /* bits within the USBPCR1 register */
53 #define USBPCR1_REFCLKSEL_SHIFT	26
54 #define USBPCR1_REFCLKSEL_MASK	(0x3 << USBPCR1_REFCLKSEL_SHIFT)
55 #define USBPCR1_REFCLKSEL_CORE	(0x2 << USBPCR1_REFCLKSEL_SHIFT)
56 #define USBPCR1_REFCLKDIV_SHIFT	24
57 #define USBPCR1_REFCLKDIV_MASK	(0x3 << USBPCR1_REFCLKDIV_SHIFT)
58 #define USBPCR1_REFCLKDIV_48	(0x2 << USBPCR1_REFCLKDIV_SHIFT)
59 #define USBPCR1_REFCLKDIV_24	(0x1 << USBPCR1_REFCLKDIV_SHIFT)
60 #define USBPCR1_REFCLKDIV_12	(0x0 << USBPCR1_REFCLKDIV_SHIFT)
61 
62 static struct ingenic_cgu *cgu;
63 
64 static unsigned long x1000_otg_phy_recalc_rate(struct clk_hw *hw,
65 						unsigned long parent_rate)
66 {
67 	u32 usbpcr1;
68 	unsigned refclk_div;
69 
70 	usbpcr1 = readl(cgu->base + CGU_REG_USBPCR1);
71 	refclk_div = usbpcr1 & USBPCR1_REFCLKDIV_MASK;
72 
73 	switch (refclk_div) {
74 	case USBPCR1_REFCLKDIV_12:
75 		return 12000000;
76 
77 	case USBPCR1_REFCLKDIV_24:
78 		return 24000000;
79 
80 	case USBPCR1_REFCLKDIV_48:
81 		return 48000000;
82 	}
83 
84 	return parent_rate;
85 }
86 
87 static long x1000_otg_phy_round_rate(struct clk_hw *hw, unsigned long req_rate,
88 				      unsigned long *parent_rate)
89 {
90 	if (req_rate < 18000000)
91 		return 12000000;
92 
93 	if (req_rate < 36000000)
94 		return 24000000;
95 
96 	return 48000000;
97 }
98 
99 static int x1000_otg_phy_set_rate(struct clk_hw *hw, unsigned long req_rate,
100 				   unsigned long parent_rate)
101 {
102 	unsigned long flags;
103 	u32 usbpcr1, div_bits;
104 
105 	switch (req_rate) {
106 	case 12000000:
107 		div_bits = USBPCR1_REFCLKDIV_12;
108 		break;
109 
110 	case 24000000:
111 		div_bits = USBPCR1_REFCLKDIV_24;
112 		break;
113 
114 	case 48000000:
115 		div_bits = USBPCR1_REFCLKDIV_48;
116 		break;
117 
118 	default:
119 		return -EINVAL;
120 	}
121 
122 	spin_lock_irqsave(&cgu->lock, flags);
123 
124 	usbpcr1 = readl(cgu->base + CGU_REG_USBPCR1);
125 	usbpcr1 &= ~USBPCR1_REFCLKDIV_MASK;
126 	usbpcr1 |= div_bits;
127 	writel(usbpcr1, cgu->base + CGU_REG_USBPCR1);
128 
129 	spin_unlock_irqrestore(&cgu->lock, flags);
130 	return 0;
131 }
132 
133 static int x1000_usb_phy_enable(struct clk_hw *hw)
134 {
135 	void __iomem *reg_opcr		= cgu->base + CGU_REG_OPCR;
136 	void __iomem *reg_usbpcr	= cgu->base + CGU_REG_USBPCR;
137 
138 	writel(readl(reg_opcr) | OPCR_SPENDN0, reg_opcr);
139 	writel(readl(reg_usbpcr) & ~USBPCR_OTG_DISABLE & ~USBPCR_SIDDQ, reg_usbpcr);
140 	return 0;
141 }
142 
143 static void x1000_usb_phy_disable(struct clk_hw *hw)
144 {
145 	void __iomem *reg_opcr		= cgu->base + CGU_REG_OPCR;
146 	void __iomem *reg_usbpcr	= cgu->base + CGU_REG_USBPCR;
147 
148 	writel(readl(reg_opcr) & ~OPCR_SPENDN0, reg_opcr);
149 	writel(readl(reg_usbpcr) | USBPCR_OTG_DISABLE | USBPCR_SIDDQ, reg_usbpcr);
150 }
151 
152 static int x1000_usb_phy_is_enabled(struct clk_hw *hw)
153 {
154 	void __iomem *reg_opcr		= cgu->base + CGU_REG_OPCR;
155 	void __iomem *reg_usbpcr	= cgu->base + CGU_REG_USBPCR;
156 
157 	return (readl(reg_opcr) & OPCR_SPENDN0) &&
158 		!(readl(reg_usbpcr) & USBPCR_SIDDQ) &&
159 		!(readl(reg_usbpcr) & USBPCR_OTG_DISABLE);
160 }
161 
162 static const struct clk_ops x1000_otg_phy_ops = {
163 	.recalc_rate = x1000_otg_phy_recalc_rate,
164 	.round_rate = x1000_otg_phy_round_rate,
165 	.set_rate = x1000_otg_phy_set_rate,
166 
167 	.enable		= x1000_usb_phy_enable,
168 	.disable	= x1000_usb_phy_disable,
169 	.is_enabled	= x1000_usb_phy_is_enabled,
170 };
171 
172 static void
173 x1000_i2spll_calc_m_n_od(const struct ingenic_cgu_pll_info *pll_info,
174 			 unsigned long rate, unsigned long parent_rate,
175 			 unsigned int *pm, unsigned int *pn, unsigned int *pod)
176 {
177 	const unsigned long m_max = GENMASK(pll_info->m_bits - 1, 0);
178 	const unsigned long n_max = GENMASK(pll_info->n_bits - 1, 0);
179 	unsigned long m, n;
180 
181 	rational_best_approximation(rate, parent_rate, m_max, n_max, &m, &n);
182 
183 	/* n should not be less than 2*m */
184 	if (n < 2 * m)
185 		n = 2 * m;
186 
187 	*pm = m;
188 	*pn = n;
189 	*pod = 1;
190 }
191 
192 static void
193 x1000_i2spll_set_rate_hook(const struct ingenic_cgu_pll_info *pll_info,
194 			   unsigned long rate, unsigned long parent_rate)
195 {
196 	/*
197 	 * Writing 0 causes I2SCDR1.I2SDIV_D to be automatically recalculated
198 	 * based on the current value of I2SCDR.I2SDIV_N, which is needed for
199 	 * the divider to function correctly.
200 	 */
201 	writel(0, cgu->base + CGU_REG_I2SCDR1);
202 }
203 
204 static const s8 pll_od_encoding[8] = {
205 	0x0, 0x1, -1, 0x2, -1, -1, -1, 0x3,
206 };
207 
208 static const struct ingenic_cgu_clk_info x1000_cgu_clocks[] = {
209 
210 	/* External clocks */
211 
212 	[X1000_CLK_EXCLK] = { "ext", CGU_CLK_EXT },
213 	[X1000_CLK_RTCLK] = { "rtc", CGU_CLK_EXT },
214 
215 	/* PLLs */
216 
217 	[X1000_CLK_APLL] = {
218 		"apll", CGU_CLK_PLL,
219 		.parents = { X1000_CLK_EXCLK },
220 		.pll = {
221 			.reg = CGU_REG_APLL,
222 			.rate_multiplier = 1,
223 			.m_shift = 24,
224 			.m_bits = 7,
225 			.m_offset = 1,
226 			.n_shift = 18,
227 			.n_bits = 5,
228 			.n_offset = 1,
229 			.od_shift = 16,
230 			.od_bits = 2,
231 			.od_max = 8,
232 			.od_encoding = pll_od_encoding,
233 			.bypass_reg = CGU_REG_APLL,
234 			.bypass_bit = 9,
235 			.enable_bit = 8,
236 			.stable_bit = 10,
237 		},
238 	},
239 
240 	[X1000_CLK_MPLL] = {
241 		"mpll", CGU_CLK_PLL,
242 		.parents = { X1000_CLK_EXCLK },
243 		.pll = {
244 			.reg = CGU_REG_MPLL,
245 			.rate_multiplier = 1,
246 			.m_shift = 24,
247 			.m_bits = 7,
248 			.m_offset = 1,
249 			.n_shift = 18,
250 			.n_bits = 5,
251 			.n_offset = 1,
252 			.od_shift = 16,
253 			.od_bits = 2,
254 			.od_max = 8,
255 			.od_encoding = pll_od_encoding,
256 			.bypass_reg = CGU_REG_MPLL,
257 			.bypass_bit = 6,
258 			.enable_bit = 7,
259 			.stable_bit = 0,
260 		},
261 	},
262 
263 	/* Custom (SoC-specific) OTG PHY */
264 
265 	[X1000_CLK_OTGPHY] = {
266 		"otg_phy", CGU_CLK_CUSTOM,
267 		.parents = { -1, -1, X1000_CLK_EXCLK, -1 },
268 		.custom = { &x1000_otg_phy_ops },
269 	},
270 
271 	/* Muxes & dividers */
272 
273 	[X1000_CLK_SCLKA] = {
274 		"sclk_a", CGU_CLK_MUX,
275 		.parents = { -1, X1000_CLK_EXCLK, X1000_CLK_APLL, -1 },
276 		.mux = { CGU_REG_CPCCR, 30, 2 },
277 	},
278 
279 	[X1000_CLK_CPUMUX] = {
280 		"cpu_mux", CGU_CLK_MUX,
281 		.parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 },
282 		.mux = { CGU_REG_CPCCR, 28, 2 },
283 	},
284 
285 	[X1000_CLK_CPU] = {
286 		"cpu", CGU_CLK_DIV | CGU_CLK_GATE,
287 		/*
288 		 * Disabling the CPU clock or any parent clocks will hang the
289 		 * system; mark it critical.
290 		 */
291 		.flags = CLK_IS_CRITICAL,
292 		.parents = { X1000_CLK_CPUMUX },
293 		.div = { CGU_REG_CPCCR, 0, 1, 4, 22, -1, -1 },
294 		.gate = { CGU_REG_CLKGR, 30 },
295 	},
296 
297 	[X1000_CLK_L2CACHE] = {
298 		"l2cache", CGU_CLK_DIV,
299 		/*
300 		 * The L2 cache clock is critical if caches are enabled and
301 		 * disabling it or any parent clocks will hang the system.
302 		 */
303 		.flags = CLK_IS_CRITICAL,
304 		.parents = { X1000_CLK_CPUMUX },
305 		.div = { CGU_REG_CPCCR, 4, 1, 4, 22, -1, -1 },
306 	},
307 
308 	[X1000_CLK_AHB0] = {
309 		"ahb0", CGU_CLK_MUX | CGU_CLK_DIV,
310 		.parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 },
311 		.mux = { CGU_REG_CPCCR, 26, 2 },
312 		.div = { CGU_REG_CPCCR, 8, 1, 4, 21, -1, -1 },
313 	},
314 
315 	[X1000_CLK_AHB2PMUX] = {
316 		"ahb2_apb_mux", CGU_CLK_MUX,
317 		.parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 },
318 		.mux = { CGU_REG_CPCCR, 24, 2 },
319 	},
320 
321 	[X1000_CLK_AHB2] = {
322 		"ahb2", CGU_CLK_DIV,
323 		.parents = { X1000_CLK_AHB2PMUX },
324 		.div = { CGU_REG_CPCCR, 12, 1, 4, 20, -1, -1 },
325 	},
326 
327 	[X1000_CLK_PCLK] = {
328 		"pclk", CGU_CLK_DIV | CGU_CLK_GATE,
329 		.parents = { X1000_CLK_AHB2PMUX },
330 		.div = { CGU_REG_CPCCR, 16, 1, 4, 20, -1, -1 },
331 		.gate = { CGU_REG_CLKGR, 28 },
332 	},
333 
334 	[X1000_CLK_DDR] = {
335 		"ddr", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE,
336 		/*
337 		 * Disabling DDR clock or its parents will render DRAM
338 		 * inaccessible; mark it critical.
339 		 */
340 		.flags = CLK_IS_CRITICAL,
341 		.parents = { -1, X1000_CLK_SCLKA, X1000_CLK_MPLL, -1 },
342 		.mux = { CGU_REG_DDRCDR, 30, 2 },
343 		.div = { CGU_REG_DDRCDR, 0, 1, 4, 29, 28, 27 },
344 		.gate = { CGU_REG_CLKGR, 31 },
345 	},
346 
347 	[X1000_CLK_MAC] = {
348 		"mac", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE,
349 		.parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL },
350 		.mux = { CGU_REG_MACCDR, 31, 1 },
351 		.div = { CGU_REG_MACCDR, 0, 1, 8, 29, 28, 27 },
352 		.gate = { CGU_REG_CLKGR, 25 },
353 	},
354 
355 	[X1000_CLK_I2SPLLMUX] = {
356 		"i2s_pll_mux", CGU_CLK_MUX,
357 		.parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL },
358 		.mux = { CGU_REG_I2SCDR, 31, 1 },
359 	},
360 
361 	[X1000_CLK_I2SPLL] = {
362 		"i2s_pll", CGU_CLK_PLL,
363 		.parents = { X1000_CLK_I2SPLLMUX },
364 		.pll = {
365 			.reg = CGU_REG_I2SCDR,
366 			.rate_multiplier = 1,
367 			.m_shift = 13,
368 			.m_bits = 9,
369 			.n_shift = 0,
370 			.n_bits = 13,
371 			.calc_m_n_od = x1000_i2spll_calc_m_n_od,
372 			.set_rate_hook = x1000_i2spll_set_rate_hook,
373 		},
374 	},
375 
376 	[X1000_CLK_I2S] = {
377 		"i2s", CGU_CLK_MUX,
378 		.parents = { X1000_CLK_EXCLK, -1, -1, X1000_CLK_I2SPLL },
379 		/*
380 		 * NOTE: the mux is at bit 30; bit 29 enables the M/N divider.
381 		 * Therefore, the divider is disabled when EXCLK is selected.
382 		 */
383 		.mux = { CGU_REG_I2SCDR, 29, 2 },
384 	},
385 
386 	[X1000_CLK_LCD] = {
387 		"lcd", CGU_CLK_MUX | CGU_CLK_DIV | CGU_CLK_GATE,
388 		.parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL },
389 		.mux = { CGU_REG_LPCDR, 31, 1 },
390 		.div = { CGU_REG_LPCDR, 0, 1, 8, 28, 27, 26 },
391 		.gate = { CGU_REG_CLKGR, 23 },
392 	},
393 
394 	[X1000_CLK_MSCMUX] = {
395 		"msc_mux", CGU_CLK_MUX,
396 		.parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL },
397 		.mux = { CGU_REG_MSC0CDR, 31, 1 },
398 	},
399 
400 	[X1000_CLK_MSC0] = {
401 		"msc0", CGU_CLK_DIV | CGU_CLK_GATE,
402 		.parents = { X1000_CLK_MSCMUX },
403 		.div = { CGU_REG_MSC0CDR, 0, 2, 8, 29, 28, 27 },
404 		.gate = { CGU_REG_CLKGR, 4 },
405 	},
406 
407 	[X1000_CLK_MSC1] = {
408 		"msc1", CGU_CLK_DIV | CGU_CLK_GATE,
409 		.parents = { X1000_CLK_MSCMUX, -1, -1, -1 },
410 		.div = { CGU_REG_MSC1CDR, 0, 2, 8, 29, 28, 27 },
411 		.gate = { CGU_REG_CLKGR, 5 },
412 	},
413 
414 	[X1000_CLK_OTG] = {
415 		"otg", CGU_CLK_DIV | CGU_CLK_GATE | CGU_CLK_MUX,
416 		.parents = { X1000_CLK_EXCLK, -1, X1000_CLK_APLL, X1000_CLK_MPLL },
417 		.mux = { CGU_REG_USBCDR, 30, 2 },
418 		.div = { CGU_REG_USBCDR, 0, 1, 8, 29, 28, 27 },
419 		.gate = { CGU_REG_CLKGR, 3 },
420 	},
421 
422 	[X1000_CLK_SSIPLL] = {
423 		"ssi_pll", CGU_CLK_MUX | CGU_CLK_DIV,
424 		.parents = { X1000_CLK_SCLKA, X1000_CLK_MPLL },
425 		.mux = { CGU_REG_SSICDR, 31, 1 },
426 		.div = { CGU_REG_SSICDR, 0, 1, 8, 29, 28, 27 },
427 	},
428 
429 	[X1000_CLK_SSIPLL_DIV2] = {
430 		"ssi_pll_div2", CGU_CLK_FIXDIV,
431 		.parents = { X1000_CLK_SSIPLL },
432 		.fixdiv = { 2 },
433 	},
434 
435 	[X1000_CLK_SSIMUX] = {
436 		"ssi_mux", CGU_CLK_MUX,
437 		.parents = { X1000_CLK_EXCLK, X1000_CLK_SSIPLL_DIV2 },
438 		.mux = { CGU_REG_SSICDR, 30, 1 },
439 	},
440 
441 	[X1000_CLK_EXCLK_DIV512] = {
442 		"exclk_div512", CGU_CLK_FIXDIV,
443 		.parents = { X1000_CLK_EXCLK },
444 		.fixdiv = { 512 },
445 	},
446 
447 	[X1000_CLK_RTC] = {
448 		"rtc_ercs", CGU_CLK_MUX | CGU_CLK_GATE,
449 		.parents = { X1000_CLK_EXCLK_DIV512, X1000_CLK_RTCLK },
450 		.mux = { CGU_REG_OPCR, 2, 1},
451 		.gate = { CGU_REG_CLKGR, 27 },
452 	},
453 
454 	/* Gate-only clocks */
455 
456 	[X1000_CLK_EMC] = {
457 		"emc", CGU_CLK_GATE,
458 		.parents = { X1000_CLK_AHB2 },
459 		.gate = { CGU_REG_CLKGR, 0 },
460 	},
461 
462 	[X1000_CLK_EFUSE] = {
463 		"efuse", CGU_CLK_GATE,
464 		.parents = { X1000_CLK_AHB2 },
465 		.gate = { CGU_REG_CLKGR, 1 },
466 	},
467 
468 	[X1000_CLK_SFC] = {
469 		"sfc", CGU_CLK_GATE,
470 		.parents = { X1000_CLK_SSIPLL },
471 		.gate = { CGU_REG_CLKGR, 2 },
472 	},
473 
474 	[X1000_CLK_I2C0] = {
475 		"i2c0", CGU_CLK_GATE,
476 		.parents = { X1000_CLK_PCLK },
477 		.gate = { CGU_REG_CLKGR, 7 },
478 	},
479 
480 	[X1000_CLK_I2C1] = {
481 		"i2c1", CGU_CLK_GATE,
482 		.parents = { X1000_CLK_PCLK },
483 		.gate = { CGU_REG_CLKGR, 8 },
484 	},
485 
486 	[X1000_CLK_I2C2] = {
487 		"i2c2", CGU_CLK_GATE,
488 		.parents = { X1000_CLK_PCLK },
489 		.gate = { CGU_REG_CLKGR, 9 },
490 	},
491 
492 	[X1000_CLK_AIC] = {
493 		"aic", CGU_CLK_GATE,
494 		.parents = { X1000_CLK_EXCLK },
495 		.gate = { CGU_REG_CLKGR, 11 },
496 	},
497 
498 	[X1000_CLK_UART0] = {
499 		"uart0", CGU_CLK_GATE,
500 		.parents = { X1000_CLK_EXCLK },
501 		.gate = { CGU_REG_CLKGR, 14 },
502 	},
503 
504 	[X1000_CLK_UART1] = {
505 		"uart1", CGU_CLK_GATE,
506 		.parents = { X1000_CLK_EXCLK},
507 		.gate = { CGU_REG_CLKGR, 15 },
508 	},
509 
510 	[X1000_CLK_UART2] = {
511 		"uart2", CGU_CLK_GATE,
512 		.parents = { X1000_CLK_EXCLK },
513 		.gate = { CGU_REG_CLKGR, 16 },
514 	},
515 
516 	[X1000_CLK_TCU] = {
517 		"tcu", CGU_CLK_GATE,
518 		.parents = { X1000_CLK_EXCLK },
519 		.gate = { CGU_REG_CLKGR, 18 },
520 	},
521 
522 	[X1000_CLK_SSI] = {
523 		"ssi", CGU_CLK_GATE,
524 		.parents = { X1000_CLK_SSIMUX },
525 		.gate = { CGU_REG_CLKGR, 19 },
526 	},
527 
528 	[X1000_CLK_OST] = {
529 		"ost", CGU_CLK_GATE,
530 		.parents = { X1000_CLK_EXCLK },
531 		.gate = { CGU_REG_CLKGR, 20 },
532 	},
533 
534 	[X1000_CLK_PDMA] = {
535 		"pdma", CGU_CLK_GATE,
536 		.parents = { X1000_CLK_EXCLK },
537 		.gate = { CGU_REG_CLKGR, 21 },
538 	},
539 };
540 
541 static void __init x1000_cgu_init(struct device_node *np)
542 {
543 	int retval;
544 
545 	cgu = ingenic_cgu_new(x1000_cgu_clocks,
546 			      ARRAY_SIZE(x1000_cgu_clocks), np);
547 	if (!cgu) {
548 		pr_err("%s: failed to initialise CGU\n", __func__);
549 		return;
550 	}
551 
552 	retval = ingenic_cgu_register_clocks(cgu);
553 	if (retval) {
554 		pr_err("%s: failed to register CGU Clocks\n", __func__);
555 		return;
556 	}
557 
558 	ingenic_cgu_register_syscore_ops(cgu);
559 }
560 /*
561  * CGU has some children devices, this is useful for probing children devices
562  * in the case where the device node is compatible with "simple-mfd".
563  */
564 CLK_OF_DECLARE_DRIVER(x1000_cgu, "ingenic,x1000-cgu", x1000_cgu_init);
565