1 /* SPDX-License-Identifier: GPL-2.0+ */
2 /*
3  * (C) Copyright 2018
4  * Mario Six, Guntermann & Drunck GmbH, mario.six@gdsys.cc
5  */
6 
7 /**
8  * enum ratio - Description of a core clock ratio
9  * @RAT_UNK:      Unknown ratio
10  * @RAT_BYP:      Bypass
11  * @RAT_1_TO_8:   Ratio 1:8
12  * @RAT_1_TO_4:   Ratio 1:4
13  * @RAT_1_TO_2:   Ratio 1:2
14  * @RAT_1_TO_1:   Ratio 1:1
15  * @RAT_1_5_TO_1: Ratio 1.5:1
16  * @RAT_2_TO_1:   Ratio 2:1
17  * @RAT_2_5_TO_1: Ratio 2.5:1
18  * @RAT_3_TO_1:   Ratio 3:1
19  */
20 #include <linux/bitops.h>
21 enum ratio {
22 	RAT_UNK,
23 	RAT_BYP,
24 	RAT_1_TO_8,
25 	RAT_1_TO_4,
26 	RAT_1_TO_2,
27 	RAT_1_TO_1,
28 	RAT_1_5_TO_1,
29 	RAT_2_TO_1,
30 	RAT_2_5_TO_1,
31 	RAT_3_TO_1
32 };
33 
34 /**
35  * struct corecnf - Description for a core clock configuration
36  * @core_csb_ratio: Core clock frequency to CSB clock frequency ratio
37  * @vco_divider: VCO divider (Core VCO frequency = Core frequency * VCO divider)
38  */
39 struct corecnf {
40 	int core_csb_ratio;
41 	int vco_divider;
42 };
43 
44 /*
45  * Table with all valid Core CSB frequency ratio / VCO divider combinations as
46  * indexed by the COREPLL field of the SPMR
47  */
48 static const struct corecnf corecnf_tab[] = {
49 	{RAT_BYP, RAT_BYP},			/* 0x00 */
50 	{RAT_BYP, RAT_BYP},			/* 0x01 */
51 	{RAT_BYP, RAT_BYP},			/* 0x02 */
52 	{RAT_BYP, RAT_BYP},			/* 0x03 */
53 	{RAT_BYP, RAT_BYP},			/* 0x04 */
54 	{RAT_BYP, RAT_BYP},			/* 0x05 */
55 	{RAT_BYP, RAT_BYP},			/* 0x06 */
56 	{RAT_BYP, RAT_BYP},			/* 0x07 */
57 	{RAT_1_TO_1, RAT_1_TO_2},		/* 0x08 */
58 	{RAT_1_TO_1, RAT_1_TO_4},		/* 0x09 */
59 	{RAT_1_TO_1, RAT_1_TO_8},		/* 0x0A */
60 	{RAT_1_TO_1, RAT_1_TO_8},		/* 0x0B */
61 	{RAT_1_5_TO_1, RAT_1_TO_2},		/* 0x0C */
62 	{RAT_1_5_TO_1, RAT_1_TO_4},		/* 0x0D */
63 	{RAT_1_5_TO_1, RAT_1_TO_8},		/* 0x0E */
64 	{RAT_1_5_TO_1, RAT_1_TO_8},		/* 0x0F */
65 	{RAT_2_TO_1, RAT_1_TO_2},		/* 0x10 */
66 	{RAT_2_TO_1, RAT_1_TO_4},		/* 0x11 */
67 	{RAT_2_TO_1, RAT_1_TO_8},		/* 0x12 */
68 	{RAT_2_TO_1, RAT_1_TO_8},		/* 0x13 */
69 	{RAT_2_5_TO_1, RAT_1_TO_2},		/* 0x14 */
70 	{RAT_2_5_TO_1, RAT_1_TO_4},		/* 0x15 */
71 	{RAT_2_5_TO_1, RAT_1_TO_8},		/* 0x16 */
72 	{RAT_2_5_TO_1, RAT_1_TO_8},		/* 0x17 */
73 	{RAT_3_TO_1, RAT_1_TO_2},		/* 0x18 */
74 	{RAT_3_TO_1, RAT_1_TO_4},		/* 0x19 */
75 	{RAT_3_TO_1, RAT_1_TO_8},		/* 0x1A */
76 	{RAT_3_TO_1, RAT_1_TO_8},		/* 0x1B */
77 };
78 
79 /**
80  * enum reg_type - Register to read a field from
81  * @REG_SCCR: Use the SCCR register
82  * @REG_SPMR: Use the SPMR register
83  */
84 enum reg_type {
85 	REG_SCCR,
86 	REG_SPMR,
87 };
88 
89 /**
90  * enum mode_type - Description of how to read a specific frequency value
91  * @TYPE_INVALID: Unknown type, will provoke error
92  * @TYPE_SCCR_STANDARD:        Read a field from the SCCR register, and use it
93  *			       as a divider for the CSB clock to compute the
94  *			       frequency
95  * @TYPE_SCCR_ONOFF:           The field describes a bit flag that can turn the
96  *			       clock on or off
97  * @TYPE_SPMR_DIRECT_MULTIPLY: Read a field from the SPMR register, and use it
98  *			       as a multiplier for the CSB clock to compute the
99  *			       frequency
100  * @TYPE_SPECIAL:              The frequency is calculated in a non-standard way
101  */
102 enum mode_type {
103 	TYPE_INVALID = 0,
104 	TYPE_SCCR_STANDARD,
105 	TYPE_SCCR_ONOFF,
106 	TYPE_SPMR_DIRECT_MULTIPLY,
107 	TYPE_SPECIAL,
108 };
109 
110 /* Map of each clock index to its human-readable name */
111 static const char * const names[] = {
112 	[MPC83XX_CLK_CORE] = "Core",
113 	[MPC83XX_CLK_CSB] = "Coherent System Bus",
114 	[MPC83XX_CLK_QE] = "QE",
115 	[MPC83XX_CLK_BRG] = "BRG",
116 	[MPC83XX_CLK_LBIU] = "Local Bus Controller",
117 	[MPC83XX_CLK_LCLK] = "Local Bus",
118 	[MPC83XX_CLK_MEM] = "DDR",
119 	[MPC83XX_CLK_MEM_SEC] = "DDR Secondary",
120 	[MPC83XX_CLK_ENC] = "SEC",
121 	[MPC83XX_CLK_I2C1] = "I2C1",
122 	[MPC83XX_CLK_I2C2] = "I2C2",
123 	[MPC83XX_CLK_TDM] = "TDM",
124 	[MPC83XX_CLK_SDHC] = "SDHC",
125 	[MPC83XX_CLK_TSEC1] = "TSEC1",
126 	[MPC83XX_CLK_TSEC2] = "TSEC2",
127 	[MPC83XX_CLK_USBDR] = "USB DR",
128 	[MPC83XX_CLK_USBMPH] = "USB MPH",
129 	[MPC83XX_CLK_PCIEXP1] = "PCIEXP1",
130 	[MPC83XX_CLK_PCIEXP2] = "PCIEXP2",
131 	[MPC83XX_CLK_SATA] = "SATA",
132 	[MPC83XX_CLK_DMAC] = "DMAC",
133 	[MPC83XX_CLK_PCI] = "PCI",
134 };
135 
136 /**
137  * struct clk_mode - Structure for clock mode descriiptions
138  * @low:  The low bit of the data field to read for this mode (may not apply to
139  *	  some modes)
140  * @high: The high bit of the data field to read for this mode (may not apply to
141  *	  some modes)
142  * @type: The type of the mode description (one of enum mode_type)
143  */
144 struct clk_mode {
145 	u8 low;
146 	u8 high;
147 	int type;
148 };
149 
150 /**
151  * set_mode() - Build a clock mode description from data
152  * @mode: The clock mode description to be filled out
153  * @low:  The low bit of the data field to read for this mode (may not apply to
154  *	  some modes)
155  * @high: The high bit of the data field to read for this mode (may not apply to
156  *	  some modes)
157  * @type: The type of the mode description (one of enum mode_type)
158  *
159  * Clock mode descriptions are a succinct description of how to read a specific
160  * clock's rate from the hardware; usually by reading a specific field of a
161  * register, such a s the SCCR register, but some types use different methods
162  * for obtaining the clock rate.
163  */
set_mode(struct clk_mode * mode,u8 low,u8 high,int type)164 static void set_mode(struct clk_mode *mode, u8 low, u8 high, int type)
165 {
166 	mode->low = low;
167 	mode->high = high;
168 	mode->type = type;
169 }
170 
171 /**
172  * retrieve_mode() - Get the clock mode description for a specific clock
173  * @clk:      The identifier of the clock for which the clock description should
174  *	      be retrieved
175  * @soc_type: The type of MPC83xx SoC for which the clock description should be
176  *	      retrieved
177  * @mode:     Pointer to a clk_mode structure to be filled with data for the
178  *	      clock
179  *
180  * Since some clock rate are stored in different places on different MPC83xx
181  * SoCs, the SoC type has to be supplied along with the clock's identifier.
182  *
183  * Return: 0 if OK, -ve on error
184  */
retrieve_mode(int clk,int soc_type,struct clk_mode * mode)185 static int retrieve_mode(int clk, int soc_type, struct clk_mode *mode)
186 {
187 	switch (clk) {
188 	case MPC83XX_CLK_CORE:
189 	case MPC83XX_CLK_CSB:
190 	case MPC83XX_CLK_QE:
191 	case MPC83XX_CLK_BRG:
192 	case MPC83XX_CLK_LCLK:
193 	case MPC83XX_CLK_I2C2:
194 		set_mode(mode, 0, 0, TYPE_SPECIAL);
195 		break;
196 	case MPC83XX_CLK_MEM:
197 		set_mode(mode, 1, 1, TYPE_SPMR_DIRECT_MULTIPLY);
198 		break;
199 	case MPC83XX_CLK_LBIU:
200 	case MPC83XX_CLK_MEM_SEC:
201 		set_mode(mode, 0, 0, TYPE_SPMR_DIRECT_MULTIPLY);
202 		break;
203 	case MPC83XX_CLK_TSEC1:
204 		set_mode(mode, 0, 1, TYPE_SCCR_STANDARD);
205 		break;
206 	case MPC83XX_CLK_TSEC2:
207 		if (soc_type == SOC_MPC8313) /* I2C and TSEC2 are the same register */
208 			set_mode(mode, 2, 3, TYPE_SCCR_STANDARD);
209 		else /* FIXME(mario.six@gdsys.cc): This has separate enable/disable bit! */
210 			set_mode(mode, 0, 1, TYPE_SCCR_STANDARD);
211 		break;
212 	case MPC83XX_CLK_SDHC:
213 		set_mode(mode, 4, 5, TYPE_SCCR_STANDARD);
214 		break;
215 	case MPC83XX_CLK_ENC:
216 		set_mode(mode, 6, 7, TYPE_SCCR_STANDARD);
217 		break;
218 	case MPC83XX_CLK_I2C1:
219 		if (soc_type == SOC_MPC8349)
220 			set_mode(mode, 2, 3, TYPE_SCCR_STANDARD);
221 		else /* I2C and ENC are the same register */
222 			set_mode(mode, 6, 7, TYPE_SCCR_STANDARD);
223 		break;
224 	case MPC83XX_CLK_PCIEXP1:
225 		set_mode(mode, 10, 11, TYPE_SCCR_STANDARD);
226 		break;
227 	case MPC83XX_CLK_PCIEXP2:
228 		set_mode(mode, 12, 13, TYPE_SCCR_STANDARD);
229 		break;
230 	case MPC83XX_CLK_USBDR:
231 		if (soc_type == SOC_MPC8313 || soc_type == SOC_MPC8349)
232 			set_mode(mode, 10, 11, TYPE_SCCR_STANDARD);
233 		else
234 			set_mode(mode, 8, 9, TYPE_SCCR_STANDARD);
235 		break;
236 	case MPC83XX_CLK_USBMPH:
237 		set_mode(mode, 8, 9, TYPE_SCCR_STANDARD);
238 		break;
239 	case MPC83XX_CLK_PCI:
240 		set_mode(mode, 15, 15, TYPE_SCCR_ONOFF);
241 		break;
242 	case MPC83XX_CLK_DMAC:
243 		set_mode(mode, 26, 27, TYPE_SCCR_STANDARD);
244 		break;
245 	case MPC83XX_CLK_SATA:
246 		/* FIXME(mario.six@gdsys.cc): All SATA controllers must have the same clock ratio */
247 		if (soc_type == SOC_MPC8379) {
248 			set_mode(mode, 24, 25, TYPE_SCCR_STANDARD);
249 			set_mode(mode, 26, 27, TYPE_SCCR_STANDARD);
250 			set_mode(mode, 28, 29, TYPE_SCCR_STANDARD);
251 			set_mode(mode, 30, 31, TYPE_SCCR_STANDARD);
252 		} else {
253 			set_mode(mode, 18, 19, TYPE_SCCR_STANDARD);
254 			set_mode(mode, 20, 21, TYPE_SCCR_STANDARD);
255 		}
256 		break;
257 	case MPC83XX_CLK_TDM:
258 		set_mode(mode, 26, 27, TYPE_SCCR_STANDARD);
259 		break;
260 	default:
261 		debug("%s: Unknown clock type %d on soc type %d\n",
262 		      __func__, clk, soc_type);
263 		set_mode(mode, 0, 0, TYPE_INVALID);
264 		return -EINVAL;
265 	}
266 
267 	return 0;
268 }
269 
270 /**
271  * get_spmr() - Read the SPMR (System PLL Mode Register)
272  * @im: Pointer to the MPC83xx main register map in question
273  *
274  * Return: The SPMR value as a 32-bit number.
275  */
get_spmr(immap_t * im)276 static inline u32 get_spmr(immap_t *im)
277 {
278 	u32 res = in_be32(&im->clk.spmr);
279 
280 	return res;
281 }
282 
283 /**
284  * get_sccr() - Read the SCCR (System Clock Control Register)
285  * @im: Pointer to the MPC83xx main register map in question
286  *
287  * Return: The SCCR value as a 32-bit number.
288  */
get_sccr(immap_t * im)289 static inline u32 get_sccr(immap_t *im)
290 {
291 	u32 res = in_be32(&im->clk.sccr);
292 
293 	return res;
294 }
295 
296 /**
297  * get_lcrr() - Read the LCRR (Clock Ratio Register)
298  * @im: Pointer to the MPC83xx main register map in question
299  *
300  * Return: The LCRR value as a 32-bit number.
301  */
get_lcrr(immap_t * im)302 static inline u32 get_lcrr(immap_t *im)
303 {
304 	u32 res = in_be32(&im->im_lbc.lcrr);
305 
306 	return res;
307 }
308 
309 /**
310  * get_pci_sync_in() - Read the PCI synchronization clock speed
311  * @im: Pointer to the MPC83xx main register map in question
312  *
313  * Return: The PCI synchronization clock speed value as a 32-bit number.
314  */
get_pci_sync_in(immap_t * im)315 static inline u32 get_pci_sync_in(immap_t *im)
316 {
317 	u8 clkin_div;
318 
319 	clkin_div = (get_spmr(im) & SPMR_CKID) >> SPMR_CKID_SHIFT;
320 	return CONFIG_SYS_CLK_FREQ / (1 + clkin_div);
321 }
322 
323 /**
324  * get_csb_clk() - Read the CSB (Coheren System Bus) clock speed
325  * @im: Pointer to the MPC83xx main register map in question
326  *
327  * Return: The CSB clock speed value as a 32-bit number.
328  */
get_csb_clk(immap_t * im)329 static inline u32 get_csb_clk(immap_t *im)
330 {
331 	u8 spmf;
332 
333 	spmf = (get_spmr(im) & SPMR_SPMF) >> SPMR_SPMF_SHIFT;
334 	return CONFIG_SYS_CLK_FREQ * spmf;
335 }
336 
337 /**
338  * spmr_field() - Read a specific SPMR field
339  * @im:   Pointer to the MPC83xx main register map in question
340  * @mask: A bitmask that describes the bitfield to be read
341  *
342  * Return: The value of the bit field as a 32-bit number.
343  */
spmr_field(immap_t * im,u32 mask)344 static inline uint spmr_field(immap_t *im, u32 mask)
345 {
346 	/* Extract shift from bitmask */
347 	uint shift = mask ? ffs(mask) - 1 : 0;
348 
349 	return (get_spmr(im) & mask) >> shift;
350 }
351 
352 /**
353  * sccr_field() - Read a specific SCCR field
354  * @im:   Pointer to the MPC83xx main register map in question
355  * @mask: A bitmask that describes the bitfield to be read
356  *
357  * Return: The value of the bit field as a 32-bit number.
358  */
sccr_field(immap_t * im,u32 mask)359 static inline uint sccr_field(immap_t *im, u32 mask)
360 {
361 	/* Extract shift from bitmask */
362 	uint shift = mask ? ffs(mask) - 1 : 0;
363 
364 	return (get_sccr(im) & mask) >> shift;
365 }
366 
367 /**
368  * lcrr_field() - Read a specific LCRR field
369  * @im:   Pointer to the MPC83xx main register map in question
370  * @mask: A bitmask that describes the bitfield to be read
371  *
372  * Return: The value of the bit field as a 32-bit number.
373  */
lcrr_field(immap_t * im,u32 mask)374 static inline uint lcrr_field(immap_t *im, u32 mask)
375 {
376 	/* Extract shift from bitmask */
377 	uint shift = mask ? ffs(mask) - 1 : 0;
378 
379 	return (get_lcrr(im) & mask) >> shift;
380 }
381