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PCI: Change all drivers to use pci_device->revision
[GitHub/LineageOS/android_kernel_motorola_exynos9610.git] / drivers / video / kyro / STG4000InitDevice.c
1 /*
2 * linux/drivers/video/kyro/STG4000InitDevice.c
3 *
4 * Copyright (C) 2000 Imagination Technologies Ltd
5 * Copyright (C) 2002 STMicroelectronics
6 *
7 * This file is subject to the terms and conditions of the GNU General Public
8 * License. See the file COPYING in the main directory of this archive
9 * for more details.
10 */
11
12 #include <linux/kernel.h>
13 #include <linux/errno.h>
14 #include <linux/types.h>
15 #include <linux/pci.h>
16
17 #include "STG4000Reg.h"
18 #include "STG4000Interface.h"
19
20 /* SDRAM fixed settings */
21 #define SDRAM_CFG_0 0x49A1
22 #define SDRAM_CFG_1 0xA732
23 #define SDRAM_CFG_2 0x31
24 #define SDRAM_ARB_CFG 0xA0
25 #define SDRAM_REFRESH 0x20
26
27 /* Reset values */
28 #define PMX2_SOFTRESET_DAC_RST 0x0001
29 #define PMX2_SOFTRESET_C1_RST 0x0004
30 #define PMX2_SOFTRESET_C2_RST 0x0008
31 #define PMX2_SOFTRESET_3D_RST 0x0010
32 #define PMX2_SOFTRESET_VIDIN_RST 0x0020
33 #define PMX2_SOFTRESET_TLB_RST 0x0040
34 #define PMX2_SOFTRESET_SD_RST 0x0080
35 #define PMX2_SOFTRESET_VGA_RST 0x0100
36 #define PMX2_SOFTRESET_ROM_RST 0x0200 /* reserved bit, do not reset */
37 #define PMX2_SOFTRESET_TA_RST 0x0400
38 #define PMX2_SOFTRESET_REG_RST 0x4000
39 #define PMX2_SOFTRESET_ALL 0x7fff
40
41 /* Core clock freq */
42 #define CORE_PLL_FREQ 1000000
43
44 /* Reference Clock freq */
45 #define REF_FREQ 14318
46
47 /* PCI Registers */
48 static u16 CorePllControl = 0x70;
49
50 #define PCI_CONFIG_SUBSYS_ID 0x2e
51
52 /* Misc */
53 #define CORE_PLL_MODE_REG_0_7 3
54 #define CORE_PLL_MODE_REG_8_15 2
55 #define CORE_PLL_MODE_CONFIG_REG 1
56 #define DAC_PLL_CONFIG_REG 0
57
58 #define STG_MAX_VCO 500000
59 #define STG_MIN_VCO 100000
60
61 /* PLL Clock */
62 #define STG4K3_PLL_SCALER 8 /* scale numbers by 2^8 for fixed point calc */
63 #define STG4K3_PLL_MIN_R 2 /* Minimum multiplier */
64 #define STG4K3_PLL_MAX_R 33 /* Max */
65 #define STG4K3_PLL_MIN_F 2 /* Minimum divisor */
66 #define STG4K3_PLL_MAX_F 513 /* Max */
67 #define STG4K3_PLL_MIN_OD 0 /* Min output divider (shift) */
68 #define STG4K3_PLL_MAX_OD 2 /* Max */
69 #define STG4K3_PLL_MIN_VCO_SC (100000000 >> STG4K3_PLL_SCALER) /* Min VCO rate */
70 #define STG4K3_PLL_MAX_VCO_SC (500000000 >> STG4K3_PLL_SCALER) /* Max VCO rate */
71 #define STG4K3_PLL_MINR_VCO_SC (100000000 >> STG4K3_PLL_SCALER) /* Min VCO rate (restricted) */
72 #define STG4K3_PLL_MAXR_VCO_SC (500000000 >> STG4K3_PLL_SCALER) /* Max VCO rate (restricted) */
73 #define STG4K3_PLL_MINR_VCO 100000000 /* Min VCO rate (restricted) */
74 #define STG4K3_PLL_MAX_VCO 500000000 /* Max VCO rate */
75 #define STG4K3_PLL_MAXR_VCO 500000000 /* Max VCO rate (restricted) */
76
77 #define OS_DELAY(X) \
78 { \
79 volatile u32 i,count=0; \
80 for(i=0;i<X;i++) count++; \
81 }
82
83 static u32 InitSDRAMRegisters(volatile STG4000REG __iomem *pSTGReg,
84 u32 dwSubSysID, u32 dwRevID)
85 {
86 u32 adwSDRAMArgCfg0[] = { 0xa0, 0x80, 0xa0, 0xa0, 0xa0 };
87 u32 adwSDRAMCfg1[] = { 0x8732, 0x8732, 0xa732, 0xa732, 0x8732 };
88 u32 adwSDRAMCfg2[] = { 0x87d2, 0x87d2, 0xa7d2, 0x87d2, 0xa7d2 };
89 u32 adwSDRAMRsh[] = { 36, 39, 40 };
90 u32 adwChipSpeed[] = { 110, 120, 125 };
91 u32 dwMemTypeIdx;
92 u32 dwChipSpeedIdx;
93
94 /* Get memory tpye and chip speed indexs from the SubSysDevID */
95 dwMemTypeIdx = (dwSubSysID & 0x70) >> 4;
96 dwChipSpeedIdx = (dwSubSysID & 0x180) >> 7;
97
98 if (dwMemTypeIdx > 4 || dwChipSpeedIdx > 2)
99 return 0;
100
101 /* Program SD-RAM interface */
102 STG_WRITE_REG(SDRAMArbiterConf, adwSDRAMArgCfg0[dwMemTypeIdx]);
103 if (dwRevID < 5) {
104 STG_WRITE_REG(SDRAMConf0, 0x49A1);
105 STG_WRITE_REG(SDRAMConf1, adwSDRAMCfg1[dwMemTypeIdx]);
106 } else {
107 STG_WRITE_REG(SDRAMConf0, 0x4DF1);
108 STG_WRITE_REG(SDRAMConf1, adwSDRAMCfg2[dwMemTypeIdx]);
109 }
110
111 STG_WRITE_REG(SDRAMConf2, 0x31);
112 STG_WRITE_REG(SDRAMRefresh, adwSDRAMRsh[dwChipSpeedIdx]);
113
114 return adwChipSpeed[dwChipSpeedIdx] * 10000;
115 }
116
117 u32 ProgramClock(u32 refClock,
118 u32 coreClock,
119 u32 * FOut, u32 * ROut, u32 * POut)
120 {
121 u32 R = 0, F = 0, OD = 0, ODIndex = 0;
122 u32 ulBestR = 0, ulBestF = 0, ulBestOD = 0;
123 u32 ulBestVCO = 0, ulBestClk = 0, ulBestScore = 0;
124 u32 ulScore, ulPhaseScore, ulVcoScore;
125 u32 ulTmp = 0, ulVCO;
126 u32 ulScaleClockReq, ulMinClock, ulMaxClock;
127 u32 ODValues[] = { 1, 2, 0 };
128
129 /* Translate clock in Hz */
130 coreClock *= 100; /* in Hz */
131 refClock *= 1000; /* in Hz */
132
133 /* Work out acceptable clock
134 * The method calculates ~ +- 0.4% (1/256)
135 */
136 ulMinClock = coreClock - (coreClock >> 8);
137 ulMaxClock = coreClock + (coreClock >> 8);
138
139 /* Scale clock required for use in calculations */
140 ulScaleClockReq = coreClock >> STG4K3_PLL_SCALER;
141
142 /* Iterate through post divider values */
143 for (ODIndex = 0; ODIndex < 3; ODIndex++) {
144 OD = ODValues[ODIndex];
145 R = STG4K3_PLL_MIN_R;
146
147 /* loop for pre-divider from min to max */
148 while (R <= STG4K3_PLL_MAX_R) {
149 /* estimate required feedback multiplier */
150 ulTmp = R * (ulScaleClockReq << OD);
151
152 /* F = ClkRequired * R * (2^OD) / Fref */
153 F = (u32)(ulTmp / (refClock >> STG4K3_PLL_SCALER));
154
155 /* compensate for accuracy */
156 if (F > STG4K3_PLL_MIN_F)
157 F--;
158
159
160 /*
161 * We should be close to our target frequency (if it's
162 * achievable with current OD & R) let's iterate
163 * through F for best fit
164 */
165 while ((F >= STG4K3_PLL_MIN_F) &&
166 (F <= STG4K3_PLL_MAX_F)) {
167 /* Calc VCO at full accuracy */
168 ulVCO = refClock / R;
169 ulVCO = F * ulVCO;
170
171 /*
172 * Check it's within restricted VCO range
173 * unless of course the desired frequency is
174 * above the restricted range, then test
175 * against VCO limit
176 */
177 if ((ulVCO >= STG4K3_PLL_MINR_VCO) &&
178 ((ulVCO <= STG4K3_PLL_MAXR_VCO) ||
179 ((coreClock > STG4K3_PLL_MAXR_VCO)
180 && (ulVCO <= STG4K3_PLL_MAX_VCO)))) {
181 ulTmp = (ulVCO >> OD); /* Clock = VCO / (2^OD) */
182
183 /* Is this clock good enough? */
184 if ((ulTmp >= ulMinClock)
185 && (ulTmp <= ulMaxClock)) {
186 ulPhaseScore = (((refClock / R) - (refClock / STG4K3_PLL_MAX_R))) / ((refClock - (refClock / STG4K3_PLL_MAX_R)) >> 10);
187
188 ulVcoScore = ((ulVCO - STG4K3_PLL_MINR_VCO)) / ((STG4K3_PLL_MAXR_VCO - STG4K3_PLL_MINR_VCO) >> 10);
189 ulScore = ulPhaseScore + ulVcoScore;
190
191 if (!ulBestScore) {
192 ulBestVCO = ulVCO;
193 ulBestOD = OD;
194 ulBestF = F;
195 ulBestR = R;
196 ulBestClk = ulTmp;
197 ulBestScore =
198 ulScore;
199 }
200 /* is this better, ( aim for highest Score) */
201 /*--------------------------------------------------------------------------
202 Here we want to use a scoring system which will take account of both the
203 value at the phase comparater and the VCO output
204 to do this we will use a cumulative score between the two
205 The way this ends up is that we choose the first value in the loop anyway
206 but we shall keep this code in case new restrictions come into play
207 --------------------------------------------------------------------------*/
208 if ((ulScore >= ulBestScore) && (OD > 0)) {
209 ulBestVCO = ulVCO;
210 ulBestOD = OD;
211 ulBestF = F;
212 ulBestR = R;
213 ulBestClk = ulTmp;
214 ulBestScore =
215 ulScore;
216 }
217 }
218 }
219 F++;
220 }
221 R++;
222 }
223 }
224
225 /*
226 did we find anything?
227 Then return RFOD
228 */
229 if (ulBestScore) {
230 *ROut = ulBestR;
231 *FOut = ulBestF;
232
233 if ((ulBestOD == 2) || (ulBestOD == 3)) {
234 *POut = 3;
235 } else
236 *POut = ulBestOD;
237
238 }
239
240 return (ulBestClk);
241 }
242
243 int SetCoreClockPLL(volatile STG4000REG __iomem *pSTGReg, struct pci_dev *pDev)
244 {
245 u32 F, R, P;
246 u16 core_pll = 0, sub;
247 u32 ulCoreClock;
248 u32 tmp;
249 u32 ulChipSpeed;
250
251 STG_WRITE_REG(IntMask, 0xFFFF);
252
253 /* Disable Primary Core Thread0 */
254 tmp = STG_READ_REG(Thread0Enable);
255 CLEAR_BIT(0);
256 STG_WRITE_REG(Thread0Enable, tmp);
257
258 /* Disable Primary Core Thread1 */
259 tmp = STG_READ_REG(Thread1Enable);
260 CLEAR_BIT(0);
261 STG_WRITE_REG(Thread1Enable, tmp);
262
263 STG_WRITE_REG(SoftwareReset,
264 PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_ROM_RST);
265 STG_WRITE_REG(SoftwareReset,
266 PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_TA_RST |
267 PMX2_SOFTRESET_ROM_RST);
268
269 /* Need to play around to reset TA */
270 STG_WRITE_REG(TAConfiguration, 0);
271 STG_WRITE_REG(SoftwareReset,
272 PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_ROM_RST);
273 STG_WRITE_REG(SoftwareReset,
274 PMX2_SOFTRESET_REG_RST | PMX2_SOFTRESET_TA_RST |
275 PMX2_SOFTRESET_ROM_RST);
276
277 pci_read_config_word(pDev, PCI_CONFIG_SUBSYS_ID, &sub);
278
279 ulChipSpeed = InitSDRAMRegisters(pSTGReg, (u32)sub,
280 (u32)pDev->revision);
281
282 if (ulChipSpeed == 0)
283 return -EINVAL;
284
285 ulCoreClock = ProgramClock(REF_FREQ, CORE_PLL_FREQ, &F, &R, &P);
286
287 core_pll |= ((P) | ((F - 2) << 2) | ((R - 2) << 11));
288
289 /* Set Core PLL Control to Core PLL Mode */
290
291 /* Send bits 0:7 of the Core PLL Mode register */
292 tmp = ((CORE_PLL_MODE_REG_0_7 << 8) | (core_pll & 0x00FF));
293 pci_write_config_word(pDev, CorePllControl, tmp);
294 /* Without some delay between the PCI config writes the clock does
295 not reliably set when the code is compiled -O3
296 */
297 OS_DELAY(1000000);
298
299 tmp |= SET_BIT(14);
300 pci_write_config_word(pDev, CorePllControl, tmp);
301 OS_DELAY(1000000);
302
303 /* Send bits 8:15 of the Core PLL Mode register */
304 tmp =
305 ((CORE_PLL_MODE_REG_8_15 << 8) | ((core_pll & 0xFF00) >> 8));
306 pci_write_config_word(pDev, CorePllControl, tmp);
307 OS_DELAY(1000000);
308
309 tmp |= SET_BIT(14);
310 pci_write_config_word(pDev, CorePllControl, tmp);
311 OS_DELAY(1000000);
312
313 STG_WRITE_REG(SoftwareReset, PMX2_SOFTRESET_ALL);
314
315 #if 0
316 /* Enable Primary Core Thread0 */
317 tmp = ((STG_READ_REG(Thread0Enable)) | SET_BIT(0));
318 STG_WRITE_REG(Thread0Enable, tmp);
319
320 /* Enable Primary Core Thread1 */
321 tmp = ((STG_READ_REG(Thread1Enable)) | SET_BIT(0));
322 STG_WRITE_REG(Thread1Enable, tmp);
323 #endif
324
325 return 0;
326 }