2 * Jz4740 common routines
5 * Ingenic Semiconductor, <jlwei@ingenic.cn>
7 * This program is free software; you can redistribute it and/or
8 * modify it under the terms of the GNU General Public License as
9 * published by the Free Software Foundation; either version 2 of
10 * the License, or (at your option) any later version.
12 * This program is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
17 * You should have received a copy of the GNU General Public License
18 * along with this program; if not, write to the Free Software
19 * Foundation, Inc., 59 Temple Place, Suite 330, Boston,
28 #include <asm/jz4740.h>
30 extern void board_early_init(void);
32 /* PLL output clock = EXTAL * NF / (NR * NO)
34 * NF = FD + 2, NR = RD + 2
35 * NO = 1 (if OD = 0), NO = 2 (if OD = 1 or 2), NO = 4 (if OD = 3)
39 register unsigned int cfcr
, plcr1
;
41 0, 0, 1, 2, 3, 0, 4, 0, 5, 0, 0, 0, 6, 0, 0, 0,
42 7, 0, 0, 0, 0, 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 0,
45 int div
[5] = {1, 3, 3, 3, 3}; /* divisors of I:S:P:L:M */
48 cfcr
= CPM_CPCCR_CLKOEN
|
50 (n2FR
[div
[0]] << CPM_CPCCR_CDIV_BIT
) |
51 (n2FR
[div
[1]] << CPM_CPCCR_HDIV_BIT
) |
52 (n2FR
[div
[2]] << CPM_CPCCR_PDIV_BIT
) |
53 (n2FR
[div
[3]] << CPM_CPCCR_MDIV_BIT
) |
54 (n2FR
[div
[4]] << CPM_CPCCR_LDIV_BIT
);
56 pllout2
= (cfcr
& CPM_CPCCR_PCS
) ? CONFIG_SYS_CPU_SPEED
: (CONFIG_SYS_CPU_SPEED
/ 2);
58 /* Init USB Host clock, pllout2 must be n*48MHz */
59 REG_CPM_UHCCDR
= pllout2
/ 48000000 - 1;
61 nf
= CONFIG_SYS_CPU_SPEED
* 2 / CONFIG_SYS_EXTAL
;
62 plcr1
= ((nf
- 2) << CPM_CPPCR_PLLM_BIT
) | /* FD */
63 (0 << CPM_CPPCR_PLLN_BIT
) | /* RD=0, NR=2 */
64 (0 << CPM_CPPCR_PLLOD_BIT
) | /* OD=0, NO=1 */
65 (0x20 << CPM_CPPCR_PLLST_BIT
) | /* PLL stable time */
66 CPM_CPPCR_PLLEN
; /* enable PLL */
70 REG_CPM_CPPCR
= plcr1
;
73 void pll_add_test(int new_freq
)
75 register unsigned int cfcr
, plcr1
;
77 0, 0, 1, 2, 3, 0, 4, 0, 5, 0, 0, 0, 6, 0, 0, 0,
78 7, 0, 0, 0, 0, 0, 0, 0, 8, 0, 0, 0, 0, 0, 0, 0,
81 int div
[5] = {1, 4, 4, 4, 4}; /* divisors of I:S:P:M:L */
84 cfcr
= CPM_CPCCR_CLKOEN
|
85 (n2FR
[div
[0]] << CPM_CPCCR_CDIV_BIT
) |
86 (n2FR
[div
[1]] << CPM_CPCCR_HDIV_BIT
) |
87 (n2FR
[div
[2]] << CPM_CPCCR_PDIV_BIT
) |
88 (n2FR
[div
[3]] << CPM_CPCCR_MDIV_BIT
) |
89 (n2FR
[div
[4]] << CPM_CPCCR_LDIV_BIT
);
91 pllout2
= (cfcr
& CPM_CPCCR_PCS
) ? new_freq
: (new_freq
/ 2);
94 REG_CPM_UHCCDR
= pllout2
/ 48000000 - 1;
96 /* nf = new_freq * 2 / CONFIG_SYS_EXTAL; */
97 nf
= new_freq
/ 1000000; /* step length is 1M */
98 plcr1
= ((nf
- 2) << CPM_CPPCR_PLLM_BIT
) | /* FD */
99 (10 << CPM_CPPCR_PLLN_BIT
) | /* RD=0, NR=2 */
100 (0 << CPM_CPPCR_PLLOD_BIT
) | /* OD=0, NO=1 */
101 (0x20 << CPM_CPPCR_PLLST_BIT
) | /* PLL stable time */
102 CPM_CPPCR_PLLEN
; /* enable PLL */
105 REG_CPM_CPCCR
= cfcr
;
106 REG_CPM_CPPCR
= plcr1
;
109 void calc_clocks_add_test(void)
111 DECLARE_GLOBAL_DATA_PTR
;
114 unsigned int div
[10] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32};
116 pllout
= __cpm_get_pllout();
118 gd
->cpu_clk
= pllout
/ div
[__cpm_get_cdiv()];
119 gd
->sys_clk
= pllout
/ div
[__cpm_get_hdiv()];
120 gd
->per_clk
= pllout
/ div
[__cpm_get_pdiv()];
121 gd
->mem_clk
= pllout
/ div
[__cpm_get_mdiv()];
122 gd
->dev_clk
= CONFIG_SYS_EXTAL
;
125 void sdram_add_test(int new_freq
)
127 register unsigned int dmcr
, sdmode
, tmp
, cpu_clk
, mem_clk
, ns
;
129 unsigned int cas_latency_sdmr
[2] = {
134 unsigned int cas_latency_dmcr
[2] = {
135 1 << EMC_DMCR_TCL_BIT
, /* CAS latency is 2 */
136 2 << EMC_DMCR_TCL_BIT
/* CAS latency is 3 */
139 int div
[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32};
142 mem_clk
= cpu_clk
* div
[__cpm_get_cdiv()] / div
[__cpm_get_mdiv()];
144 REG_EMC_RTCSR
= EMC_RTCSR_CKS_DISABLE
;
148 /* Basic DMCR register value. */
149 dmcr
= ((SDRAM_ROW
-11)<<EMC_DMCR_RA_BIT
) |
150 ((SDRAM_COL
-8)<<EMC_DMCR_CA_BIT
) |
151 (SDRAM_BANK4
<<EMC_DMCR_BA_BIT
) |
152 (SDRAM_BW16
<<EMC_DMCR_BW_BIT
) |
154 cas_latency_dmcr
[((SDRAM_CASL
== 3) ? 1 : 0)];
156 /* SDRAM timimg parameters */
157 ns
= 1000000000 / mem_clk
;
161 if (tmp
< 4) tmp
= 4;
162 if (tmp
> 11) tmp
= 11;
163 dmcr
|= ((tmp
-4) << EMC_DMCR_TRAS_BIT
);
166 if (tmp
> 3) tmp
= 3;
167 dmcr
|= (tmp
<< EMC_DMCR_RCD_BIT
);
170 if (tmp
> 7) tmp
= 7;
171 dmcr
|= (tmp
<< EMC_DMCR_TPC_BIT
);
174 if (tmp
> 3) tmp
= 3;
175 dmcr
|= (tmp
<< EMC_DMCR_TRWL_BIT
);
177 tmp
= (SDRAM_TRAS
+ SDRAM_TPC
)/ns
;
178 if (tmp
> 14) tmp
= 14;
179 dmcr
|= (((tmp
+ 1) >> 1) << EMC_DMCR_TRC_BIT
);
184 /* First, precharge phase */
187 /* Set refresh registers */
190 if (tmp
> 0xff) tmp
= 0xff;
193 REG_EMC_RTCSR
= EMC_RTCSR_CKS_64
; /* Divisor is 64, CKO/64 */
195 /* SDRAM mode values */
196 sdmode
= EMC_SDMR_BT_SEQ
|
199 cas_latency_sdmr
[((SDRAM_CASL
== 3) ? 1 : 0)];
201 /* precharge all chip-selects */
202 REG8(EMC_SDMR0
|sdmode
) = 0;
204 /* wait for precharge, > 200us */
205 tmp
= (cpu_clk
/ 1000000) * 200;
208 /* enable refresh and set SDRAM mode */
209 REG_EMC_DMCR
= dmcr
| EMC_DMCR_RFSH
| EMC_DMCR_MRSET
;
211 /* write sdram mode register for each chip-select */
212 REG8(EMC_SDMR0
|sdmode
) = 0;
214 /* everything is ok now */
217 void sdram_init(void)
219 register unsigned int dmcr0
, dmcr
, sdmode
, tmp
, cpu_clk
, mem_clk
, ns
;
221 unsigned int cas_latency_sdmr
[2] = {
226 unsigned int cas_latency_dmcr
[2] = {
227 1 << EMC_DMCR_TCL_BIT
, /* CAS latency is 2 */
228 2 << EMC_DMCR_TCL_BIT
/* CAS latency is 3 */
231 int div
[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32};
233 cpu_clk
= CONFIG_SYS_CPU_SPEED
;
234 mem_clk
= cpu_clk
* div
[__cpm_get_cdiv()] / div
[__cpm_get_mdiv()];
236 REG_EMC_BCR
= 0; /* Disable bus release */
237 REG_EMC_RTCSR
= 0; /* Disable clock for counting */
239 /* Fault DMCR value for mode register setting*/
240 #define SDRAM_ROW0 11
242 #define SDRAM_BANK40 0
244 dmcr0
= ((SDRAM_ROW0
-11)<<EMC_DMCR_RA_BIT
) |
245 ((SDRAM_COL0
-8)<<EMC_DMCR_CA_BIT
) |
246 (SDRAM_BANK40
<<EMC_DMCR_BA_BIT
) |
247 (SDRAM_BW16
<<EMC_DMCR_BW_BIT
) |
249 cas_latency_dmcr
[((SDRAM_CASL
== 3) ? 1 : 0)];
251 /* Basic DMCR value */
252 dmcr
= ((SDRAM_ROW
-11)<<EMC_DMCR_RA_BIT
) |
253 ((SDRAM_COL
-8)<<EMC_DMCR_CA_BIT
) |
254 (SDRAM_BANK4
<<EMC_DMCR_BA_BIT
) |
255 (SDRAM_BW16
<<EMC_DMCR_BW_BIT
) |
257 cas_latency_dmcr
[((SDRAM_CASL
== 3) ? 1 : 0)];
260 ns
= 1000000000 / mem_clk
;
262 if (tmp
< 4) tmp
= 4;
263 if (tmp
> 11) tmp
= 11;
264 dmcr
|= ((tmp
-4) << EMC_DMCR_TRAS_BIT
);
266 if (tmp
> 3) tmp
= 3;
267 dmcr
|= (tmp
<< EMC_DMCR_RCD_BIT
);
269 if (tmp
> 7) tmp
= 7;
270 dmcr
|= (tmp
<< EMC_DMCR_TPC_BIT
);
272 if (tmp
> 3) tmp
= 3;
273 dmcr
|= (tmp
<< EMC_DMCR_TRWL_BIT
);
274 tmp
= (SDRAM_TRAS
+ SDRAM_TPC
)/ns
;
275 if (tmp
> 14) tmp
= 14;
276 dmcr
|= (((tmp
+ 1) >> 1) << EMC_DMCR_TRC_BIT
);
278 /* SDRAM mode value */
279 sdmode
= EMC_SDMR_BT_SEQ
|
282 cas_latency_sdmr
[((SDRAM_CASL
== 3) ? 1 : 0)];
284 /* Stage 1. Precharge all banks by writing SDMR with DMCR.MRSET=0 */
286 REG8(EMC_SDMR0
|sdmode
) = 0;
288 /* Wait for precharge, > 200us */
289 tmp
= (cpu_clk
/ 1000000) * 1000;
292 /* Stage 2. Enable auto-refresh */
293 REG_EMC_DMCR
= dmcr
| EMC_DMCR_RFSH
;
297 if (tmp
> 0xff) tmp
= 0xff;
300 REG_EMC_RTCSR
= EMC_RTCSR_CKS_64
; /* Divisor is 64, CKO/64 */
302 /* Wait for number of auto-refresh cycles */
303 tmp
= (cpu_clk
/ 1000000) * 1000;
306 /* Stage 3. Mode Register Set */
307 REG_EMC_DMCR
= dmcr0
| EMC_DMCR_RFSH
| EMC_DMCR_MRSET
;
308 REG8(EMC_SDMR0
|sdmode
) = 0;
310 /* Set back to basic DMCR value */
311 REG_EMC_DMCR
= dmcr
| EMC_DMCR_RFSH
| EMC_DMCR_MRSET
;
313 /* everything is ok now */
316 #ifndef CONFIG_NAND_SPL
318 static void calc_clocks(void)
320 DECLARE_GLOBAL_DATA_PTR
;
323 unsigned int div
[10] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32};
325 pllout
= __cpm_get_pllout();
327 gd
->cpu_clk
= pllout
/ div
[__cpm_get_cdiv()];
328 gd
->sys_clk
= pllout
/ div
[__cpm_get_hdiv()];
329 gd
->per_clk
= pllout
/ div
[__cpm_get_pdiv()];
330 gd
->mem_clk
= pllout
/ div
[__cpm_get_mdiv()];
331 gd
->dev_clk
= CONFIG_SYS_EXTAL
;
334 static void rtc_init(void)
336 unsigned long rtcsta
;
338 while ( !__rtc_write_ready()) ;
339 __rtc_enable_alarm(); /* enable alarm */
341 while ( !__rtc_write_ready())
343 REG_RTC_RGR
= 0x00007fff; /* type value */
345 while ( !__rtc_write_ready())
347 REG_RTC_HWFCR
= 0x0000ffe0; /* Power on delay 2s */
349 while ( !__rtc_write_ready())
351 REG_RTC_HRCR
= 0x00000fe0; /* reset delay 125ms */
353 while ( !__rtc_write_ready())
355 rtcsta
= REG_RTC_HWRSR
;
356 while ( !__rtc_write_ready())
360 while ( !__rtc_write_ready())
364 while ( !__rtc_write_ready())
372 * jz4740 board init routine
374 int jz_board_init(void)
376 board_early_init(); /* init gpio, pll etc. */
377 #ifndef CONFIG_NAND_U_BOOT
378 pll_init(); /* init PLL */
379 sdram_init(); /* init sdram memory */
381 calc_clocks(); /* calc the clocks */
382 rtc_init(); /* init rtc on any reset: */
386 /* U-Boot common routines */
387 phys_size_t
initdram(int board_type
)
390 u32 rows
, cols
, dw
, banks
;
394 rows
= 11 + ((dmcr
& EMC_DMCR_RA_MASK
) >> EMC_DMCR_RA_BIT
);
395 cols
= 8 + ((dmcr
& EMC_DMCR_CA_MASK
) >> EMC_DMCR_CA_BIT
);
396 dw
= (dmcr
& EMC_DMCR_BW
) ? 2 : 4;
397 banks
= (dmcr
& EMC_DMCR_BA
) ? 4 : 2;
399 size
= (1 << (rows
+ cols
)) * dw
* banks
;
409 #define TIMER_FDATA 0xffff /* Timer full data value */
410 #define TIMER_HZ CONFIG_SYS_HZ
412 #define READ_TIMER REG_TCU_TCNT(TIMER_CHAN) /* macro to read the 16 bit timer */
414 static ulong timestamp
;
415 static ulong lastdec
;
417 void reset_timer_masked (void);
418 ulong
get_timer_masked (void);
419 void udelay_masked (unsigned long usec
);
422 * timer without interrupts
427 REG_TCU_TCSR(TIMER_CHAN
) = TCU_TCSR_PRESCALE256
| TCU_TCSR_EXT_EN
;
428 REG_TCU_TCNT(TIMER_CHAN
) = 0;
429 REG_TCU_TDHR(TIMER_CHAN
) = 0;
430 REG_TCU_TDFR(TIMER_CHAN
) = TIMER_FDATA
;
432 REG_TCU_TMSR
= (1 << TIMER_CHAN
) | (1 << (TIMER_CHAN
+ 16)); /* mask irqs */
433 REG_TCU_TSCR
= (1 << TIMER_CHAN
); /* enable timer clock */
434 REG_TCU_TESR
= (1 << TIMER_CHAN
); /* start counting up */
442 void reset_timer(void)
444 reset_timer_masked ();
447 ulong
get_timer(ulong base
)
449 return get_timer_masked () - base
;
452 void set_timer(ulong t
)
457 void udelay (unsigned long usec
)
469 tmo
= usec
* TIMER_HZ
;
476 /* check for rollover during this delay */
478 if ((tmp
+ tmo
) < tmp
)
479 reset_timer_masked(); /* timer would roll over */
483 while (get_timer_masked () < tmo
);
486 void reset_timer_masked (void)
489 lastdec
= READ_TIMER
;
493 ulong
get_timer_masked (void)
495 ulong now
= READ_TIMER
;
497 if (lastdec
<= now
) {
499 timestamp
+= (now
- lastdec
);
501 /* we have an overflow ... */
502 timestamp
+= TIMER_FDATA
+ now
- lastdec
;
509 void udelay_masked (unsigned long usec
)
522 tmo
= usec
* TIMER_HZ
;
529 endtime
= get_timer_masked () + tmo
;
532 ulong now
= get_timer_masked ();
533 diff
= endtime
- now
;
538 * This function is derived from PowerPC code (read timebase as long long).
539 * On MIPS it just returns the timer value.
541 unsigned long long get_ticks(void)
547 * This function is derived from PowerPC code (timebase clock frequency).
548 * On MIPS it returns the number of timer ticks per second.
550 ulong
get_tbclk (void)
555 #endif /* CONFIG_NAND_SPL */
557 /* End of timer routine. */
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