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Luma3DS-3GX/source/screen.c
2017-04-17 03:59:45 +02:00

297 lines
8.9 KiB
C

/*
* This file is part of Luma3DS
* Copyright (C) 2016 Aurora Wright, TuxSH
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
* Additional Terms 7.b of GPLv3 applies to this file: Requiring preservation of specified
* reasonable legal notices or author attributions in that material or in the Appropriate Legal
* Notices displayed by works containing it.
*/
/*
* Screen init code by dark_samus, bil1s, Normmatt, delebile and others
* Screen deinit code by tiniVi
*/
/*
* About cache coherency:
*
* Flushing the data cache for all memory regions read from/written to by both processors is mandatory on the ARM9 processor.
* Thus, we make sure there'll be a cache miss on the ARM9 next time it's read.
* Otherwise the ARM9 won't see the changes made and things will break.
*
* On the ARM11, in the environment we're in, the MMU isn't enabled and nothing is cached.
*/
#include "screen.h"
#include "config.h"
#include "memory.h"
#include "cache.h"
#include "i2c.h"
#include "utils.h"
vu32 *arm11Entry = (vu32 *)BRAHMA_ARM11_ENTRY;
static const u32 brightness[4] = {0x5F, 0x4C, 0x39, 0x26};
void __attribute__((naked)) arm11Stub(void)
{
WAIT_FOR_ARM9();
}
static void invokeArm11Function(void (*func)())
{
static bool hasCopiedStub = false;
if(!hasCopiedStub)
{
memcpy((void *)ARM11_STUB_ADDRESS, arm11Stub, 0x2C);
hasCopiedStub = true;
}
*arm11Entry = (u32)func;
while(*arm11Entry);
*arm11Entry = ARM11_STUB_ADDRESS;
while(*arm11Entry);
}
void deinitScreens(void)
{
void __attribute__((naked)) ARM11(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
//Shutdown LCDs
*(vu32 *)0x10202A44 = 0;
*(vu32 *)0x10202244 = 0;
*(vu32 *)0x10202014 = 0;
WAIT_FOR_ARM9();
}
if(ARESCREENSINITIALIZED) invokeArm11Function(ARM11);
}
void updateBrightness(u32 brightnessIndex)
{
static u32 brightnessLevel;
brightnessLevel = brightness[brightnessIndex];
void __attribute__((naked)) ARM11(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
//Change brightness
*(vu32 *)0x10202240 = brightnessLevel;
*(vu32 *)0x10202A40 = brightnessLevel;
WAIT_FOR_ARM9();
}
flushDCacheRange(&brightnessLevel, 4);
invokeArm11Function(ARM11);
}
void swapFramebuffers(bool isAlternate)
{
static u32 isAlternateTmp;
isAlternateTmp = isAlternate ? 1 : 0;
void __attribute__((naked)) ARM11(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
*(vu32 *)0x10400478 = (*(vu32 *)0x10400478 & 0xFFFFFFFE) | isAlternateTmp;
*(vu32 *)0x10400578 = (*(vu32 *)0x10400478 & 0xFFFFFFFE) | isAlternateTmp;
WAIT_FOR_ARM9();
}
flushDCacheRange(&isAlternateTmp, 4);
invokeArm11Function(ARM11);
}
void clearScreens(bool isAlternate)
{
static volatile struct fb *fbTmp;
fbTmp = isAlternate ? &fbs[1] : &fbs[0];
void __attribute__((naked)) ARM11(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
//Setting up two simultaneous memory fills using the GPU
vu32 *REGs_PSC0 = (vu32 *)0x10400010,
*REGs_PSC1 = (vu32 *)0x10400020;
REGs_PSC0[0] = (u32)fbTmp->top_left >> 3; //Start address
REGs_PSC0[1] = (u32)(fbTmp->top_left + SCREEN_TOP_FBSIZE) >> 3; //End address
REGs_PSC0[2] = 0; //Fill value
REGs_PSC0[3] = (2 << 8) | 1; //32-bit pattern; start
REGs_PSC1[0] = (u32)fbTmp->bottom >> 3; //Start address
REGs_PSC1[1] = (u32)(fbTmp->bottom + SCREEN_BOTTOM_FBSIZE) >> 3; //End address
REGs_PSC1[2] = 0; //Fill value
REGs_PSC1[3] = (2 << 8) | 1; //32-bit pattern; start
while(!((REGs_PSC0[3] & 2) && (REGs_PSC1[3] & 2)));
WAIT_FOR_ARM9();
}
flushDCacheRange((void *)fbTmp, sizeof(struct fb));
flushDCacheRange(&fbTmp, 4);
invokeArm11Function(ARM11);
}
void initScreens(void)
{
void __attribute__((naked)) initSequence(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
u32 brightnessLevel = brightness[MULTICONFIG(BRIGHTNESS)];
*(vu32 *)0x10141200 = 0x1007F;
*(vu32 *)0x10202014 = 0x00000001;
*(vu32 *)0x1020200C &= 0xFFFEFFFE;
*(vu32 *)0x10202240 = brightnessLevel;
*(vu32 *)0x10202A40 = brightnessLevel;
*(vu32 *)0x10202244 = 0x1023E;
*(vu32 *)0x10202A44 = 0x1023E;
//Top screen
*(vu32 *)0x10400400 = 0x000001c2;
*(vu32 *)0x10400404 = 0x000000d1;
*(vu32 *)0x10400408 = 0x000001c1;
*(vu32 *)0x1040040c = 0x000001c1;
*(vu32 *)0x10400410 = 0x00000000;
*(vu32 *)0x10400414 = 0x000000cf;
*(vu32 *)0x10400418 = 0x000000d1;
*(vu32 *)0x1040041c = 0x01c501c1;
*(vu32 *)0x10400420 = 0x00010000;
*(vu32 *)0x10400424 = 0x0000019d;
*(vu32 *)0x10400428 = 0x00000002;
*(vu32 *)0x1040042c = 0x00000192;
*(vu32 *)0x10400430 = 0x00000192;
*(vu32 *)0x10400434 = 0x00000192;
*(vu32 *)0x10400438 = 0x00000001;
*(vu32 *)0x1040043c = 0x00000002;
*(vu32 *)0x10400440 = 0x01960192;
*(vu32 *)0x10400444 = 0x00000000;
*(vu32 *)0x10400448 = 0x00000000;
*(vu32 *)0x1040045C = 0x00f00190;
*(vu32 *)0x10400460 = 0x01c100d1;
*(vu32 *)0x10400464 = 0x01920002;
*(vu32 *)0x10400468 = 0x18300000;
*(vu32 *)0x10400470 = 0x80341;
*(vu32 *)0x10400474 = 0x00010501;
*(vu32 *)0x10400478 = 0;
*(vu32 *)0x10400490 = 0x000002D0;
*(vu32 *)0x1040049C = 0x00000000;
//Disco register
for(u32 i = 0; i < 256; i++)
*(vu32 *)0x10400484 = 0x10101 * i;
//Bottom screen
*(vu32 *)0x10400500 = 0x000001c2;
*(vu32 *)0x10400504 = 0x000000d1;
*(vu32 *)0x10400508 = 0x000001c1;
*(vu32 *)0x1040050c = 0x000001c1;
*(vu32 *)0x10400510 = 0x000000cd;
*(vu32 *)0x10400514 = 0x000000cf;
*(vu32 *)0x10400518 = 0x000000d1;
*(vu32 *)0x1040051c = 0x01c501c1;
*(vu32 *)0x10400520 = 0x00010000;
*(vu32 *)0x10400524 = 0x0000019d;
*(vu32 *)0x10400528 = 0x00000052;
*(vu32 *)0x1040052c = 0x00000192;
*(vu32 *)0x10400530 = 0x00000192;
*(vu32 *)0x10400534 = 0x0000004f;
*(vu32 *)0x10400538 = 0x00000050;
*(vu32 *)0x1040053c = 0x00000052;
*(vu32 *)0x10400540 = 0x01980194;
*(vu32 *)0x10400544 = 0x00000000;
*(vu32 *)0x10400548 = 0x00000011;
*(vu32 *)0x1040055C = 0x00f00140;
*(vu32 *)0x10400560 = 0x01c100d1;
*(vu32 *)0x10400564 = 0x01920052;
*(vu32 *)0x10400568 = 0x18300000 + 0x46500;
*(vu32 *)0x10400570 = 0x80301;
*(vu32 *)0x10400574 = 0x00010501;
*(vu32 *)0x10400578 = 0;
*(vu32 *)0x10400590 = 0x000002D0;
*(vu32 *)0x1040059C = 0x00000000;
//Disco register
for(u32 i = 0; i < 256; i++)
*(vu32 *)0x10400584 = 0x10101 * i;
WAIT_FOR_ARM9();
}
//Set CakeBrah framebuffers
void __attribute__((naked)) setupFramebuffers(void)
{
//Disable interrupts
__asm(".word 0xF10C01C0");
fbs[0].top_left = (u8 *)0x18300000;
fbs[1].top_left = (u8 *)0x18400000;
fbs[0].top_right = (u8 *)0x18300000;
fbs[1].top_right = (u8 *)0x18400000;
fbs[0].bottom = (u8 *)0x18346500;
fbs[1].bottom = (u8 *)0x18446500;
*(vu32 *)0x10400468 = (u32)fbs[0].top_left;
*(vu32 *)0x1040046c = (u32)fbs[1].top_left;
*(vu32 *)0x10400494 = (u32)fbs[0].top_right;
*(vu32 *)0x10400498 = (u32)fbs[1].top_right;
*(vu32 *)0x10400568 = (u32)fbs[0].bottom;
*(vu32 *)0x1040056c = (u32)fbs[1].bottom;
WAIT_FOR_ARM9();
}
static bool needToSetup = true;
if(needToSetup)
{
if(!ARESCREENSINITIALIZED)
{
flushDCacheRange(&configData, sizeof(CfgData));
invokeArm11Function(initSequence);
//Turn on backlight
i2cWriteRegister(I2C_DEV_MCU, 0x22, 0x2A);
wait(3ULL);
}
else updateBrightness(MULTICONFIG(BRIGHTNESS));
flushDCacheRange((void *)fbs, 2 * sizeof(struct fb));
invokeArm11Function(setupFramebuffers);
needToSetup = false;
}
clearScreens(false);
swapFramebuffers(false);
}