/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Rockbox driver for iPod LCDs * * Based on code from the ipodlinux project - http://ipodlinux.org/ * Adapted for Rockbox in November 2005 * * Original file: linux/arch/armnommu/mach-ipod/fb.c * * Copyright (c) 2003-2005 Bernard Leach (leachbj@bouncycastle.org) * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #include "cpu.h" #include "lcd.h" #include "kernel.h" #include "system.h" /* check if number of useconds has past */ static inline bool timer_check(int clock_start, int usecs) { return ((int)(USEC_TIMER - clock_start)) >= usecs; } #if (CONFIG_LCD == LCD_IPOD2BPP) || (CONFIG_LCD == LCD_IPODMINI) /*** hardware configuration ***/ #if CONFIG_CPU == PP5002 #define IPOD_LCD_BASE 0xc0001000 #define IPOD_LCD_BUSY_MASK 0x80000000 #else /* PP5020 */ #define IPOD_LCD_BASE 0x70003000 #define IPOD_LCD_BUSY_MASK 0x00008000 #endif /* LCD command codes for HD66753 */ #define LCD_CMD 0x08 #define LCD_DATA 0x10 #define R_START_OSC 0x00 #define R_DRV_OUTPUT_CONTROL 0x01 #define R_DRV_WAVEFORM_CONTROL 0x02 #define R_POWER_CONTROL 0x03 #define R_CONTRAST_CONTROL 0x04 #define R_ENTRY_MODE 0x05 #define R_ROTATION 0x06 #define R_DISPLAY_CONTROL 0x07 #define R_CURSOR_CONTROL 0x08 #define R_HORIZONTAL_CURSOR_POS 0x0b #define R_VERTICAL_CURSOR_POS 0x0c #define R_1ST_SCR_DRV_POS 0x0d #define R_2ND_SCR_DRV_POS 0x0e #define R_RAM_WRITE_MASK 0x10 #define R_RAM_ADDR_SET 0x11 #define R_RAM_DATA 0x12 /* needed for flip */ static int addr_offset; #if defined(IPOD_MINI) || defined(IPOD_MINI2G) static int pix_offset; #endif static const unsigned char dibits[16] ICONST_ATTR = { 0x00, 0x03, 0x0C, 0x0F, 0x30, 0x33, 0x3C, 0x3F, 0xC0, 0xC3, 0xCC, 0xCF, 0xF0, 0xF3, 0xFC, 0xFF }; /* wait for LCD with timeout */ static inline void lcd_wait_write(void) { int start = USEC_TIMER; do { if ((inl(IPOD_LCD_BASE) & 0x8000) == 0) break; } while (timer_check(start, 1000) == 0); } /* send LCD data */ static void lcd_send_data(unsigned data) { lcd_wait_write(); #ifdef IPOD_MINI2G outl((inl(IPOD_LCD_BASE) & ~0x1f00000) | 0x1700000, IPOD_LCD_BASE); outl(data | 0x760000, IPOD_LCD_BASE+8); #else outl(data >> 8, IPOD_LCD_BASE + LCD_DATA); lcd_wait_write(); outl(data & 0xff, IPOD_LCD_BASE + LCD_DATA); #endif } /* send LCD command */ static void lcd_prepare_cmd(unsigned cmd) { lcd_wait_write(); #ifdef IPOD_MINI2G outl((inl(IPOD_LCD_BASE) & ~0x1f00000) | 0x1700000, IPOD_LCD_BASE); outl(cmd | 0x740000, IPOD_LCD_BASE+8); #else outl(0x0, IPOD_LCD_BASE + LCD_CMD); lcd_wait_write(); outl(cmd, IPOD_LCD_BASE + LCD_CMD); #endif } /* send LCD command and data */ static void lcd_cmd_and_data(unsigned cmd, unsigned data) { lcd_prepare_cmd(cmd); lcd_send_data(data); } /* LCD init */ void lcd_init_device(void) { lcd_cmd_and_data(R_DISPLAY_CONTROL, 0x0009); lcd_set_flip(false); lcd_cmd_and_data(R_ENTRY_MODE, 0x0000); #ifdef IPOD_4G outl(inl(0x6000d004) | 0x4, 0x6000d004); /* B02 enable */ outl(inl(0x6000d004) | 0x8, 0x6000d004); /* B03 enable */ outl(inl(0x70000084) | 0x2000000, 0x70000084); /* D01 enable */ outl(inl(0x70000080) | 0x2000000, 0x70000080); /* D01 =1 */ outl(inl(0x6000600c) | 0x20000, 0x6000600c); /* PWM enable */ #endif } /*** hardware configuration ***/ int lcd_default_contrast(void) { #if defined(IPOD_MINI) || defined(IPOD_MINI2G) || defined(IPOD_3G) return 42; #else return 35; #endif } /* Rockbox stores the contrast as 0..63 - we add 64 to it */ void lcd_set_contrast(int val) { if (val < 0) val = 0; else if (val > 63) val = 63; lcd_cmd_and_data(R_CONTRAST_CONTROL, 0x400 | (val + 64)); } void lcd_set_invert_display(bool yesno) { if (yesno) lcd_cmd_and_data(R_DISPLAY_CONTROL, 0x0023); else lcd_cmd_and_data(R_DISPLAY_CONTROL, 0x0009); } /* turn the display upside down (call lcd_update() afterwards) */ void lcd_set_flip(bool yesno) { #if defined(IPOD_MINI) || defined(IPOD_MINI2G) if (yesno) { /* 168x112, inverse COM order */ lcd_cmd_and_data(R_DRV_OUTPUT_CONTROL, 0x020d); lcd_cmd_and_data(R_1ST_SCR_DRV_POS, 0x8316); /* 22..131 */ addr_offset = (22 << 5) | (20 - 4); pix_offset = -2; } else { /* 168x112, inverse SEG order */ lcd_cmd_and_data(R_DRV_OUTPUT_CONTROL, 0x010d); lcd_cmd_and_data(R_1ST_SCR_DRV_POS, 0x6d00); /* 0..109 */ addr_offset = 20; pix_offset = 0; } #else if (yesno) { /* 168x128, inverse SEG & COM order */ lcd_cmd_and_data(R_DRV_OUTPUT_CONTROL, 0x030f); lcd_cmd_and_data(R_1ST_SCR_DRV_POS, 0x8304); /* 4..131 */ addr_offset = (4 << 5) | (20 - 1); } else { /* 168x128 */ lcd_cmd_and_data(R_DRV_OUTPUT_CONTROL, 0x000f); lcd_cmd_and_data(R_1ST_SCR_DRV_POS, 0x7f00); /* 0..127 */ addr_offset = 20; } #endif } /*** update functions ***/ /* Performance function that works with an external buffer note that x, bwidtht and stride are in 8-pixel units! */ void lcd_blit(const unsigned char* data, int bx, int y, int bwidth, int height, int stride) { const unsigned char *src, *src_end; while (height--) { src = data; src_end = data + bwidth; lcd_cmd_and_data(R_RAM_ADDR_SET, (y++ << 5) + addr_offset - bx); lcd_prepare_cmd(R_RAM_DATA); do { unsigned byte = *src++; lcd_send_data((dibits[byte>>4] << 8) | dibits[byte&0x0f]); } while (src < src_end); data += stride; } } void lcd_update_rect(int x, int y, int width, int height) { int xmax, ymax; if (x + width > LCD_WIDTH) width = LCD_WIDTH - x; if (width <= 0) return; ymax = y + height - 1; if (ymax >= LCD_HEIGHT) ymax = LCD_HEIGHT - 1; #if defined(IPOD_MINI) || defined(IPOD_MINI2G) x += pix_offset; #endif /* writing is done in 16-bit units (8 pixels) */ xmax = (x + width - 1) >> 3; x >>= 3; width = xmax - x + 1; for (; y <= ymax; y++) { unsigned char *data, *data_end; lcd_cmd_and_data(R_RAM_ADDR_SET, (y << 5) + addr_offset - x); lcd_prepare_cmd(R_RAM_DATA); data = &lcd_framebuffer[y][2*x]; data_end = data + 2 * width; #if defined(IPOD_MINI) || defined(IPOD_MINI2G) if (pix_offset == -2) { unsigned cur_word = *data++; do { cur_word = (cur_word << 8) | *data++; cur_word = (cur_word << 8) | *data++; lcd_send_data((cur_word >> 4) & 0xffff); } while (data <= data_end); } else #endif { do { unsigned highbyte = *data++; lcd_send_data((highbyte << 8) | *data++); } while (data < data_end); } } } /* Update the display. */ void lcd_update(void) { lcd_update_rect(0, 0, LCD_WIDTH, LCD_HEIGHT); } #else #define IPOD_LCD_BASE 0x70008a0c #define IPOD_LCD_BUSY_MASK 0x80000000 /* LCD command codes for HD66789R */ #define LCD_CNTL_RAM_ADDR_SET 0x21 #define LCD_CNTL_WRITE_TO_GRAM 0x22 #define LCD_CNTL_HORIZ_RAM_ADDR_POS 0x44 #define LCD_CNTL_VERT_RAM_ADDR_POS 0x45 /*** globals ***/ static int lcd_type = 1; /* 0 = "old" Color/Photo, 1 = "new" Color & Nano */ static void lcd_wait_write(void) { if ((inl(IPOD_LCD_BASE) & IPOD_LCD_BUSY_MASK) != 0) { int start = USEC_TIMER; do { if ((inl(IPOD_LCD_BASE) & IPOD_LCD_BUSY_MASK) == 0) break; } while (timer_check(start, 1000) == 0); } } static void lcd_send_lo(int v) { lcd_wait_write(); outl(v | 0x80000000, IPOD_LCD_BASE); } static void lcd_send_hi(int v) { lcd_wait_write(); outl(v | 0x81000000, IPOD_LCD_BASE); } static void lcd_cmd_data(int cmd, int data) { if (lcd_type == 0) { lcd_send_lo(cmd); lcd_send_lo(data); } else { lcd_send_lo(0x0); lcd_send_lo(cmd); lcd_send_hi((data >> 8) & 0xff); lcd_send_hi(data & 0xff); } } /*** hardware configuration ***/ void lcd_set_contrast(int val) { /* TODO: Implement lcd_set_contrast() */ (void)val; } void lcd_set_invert_display(bool yesno) { /* TODO: Implement lcd_set_invert_display() */ (void)yesno; } /* turn the display upside down (call lcd_update() afterwards) */ void lcd_set_flip(bool yesno) { /* TODO: Implement lcd_set_flip() */ (void)yesno; } /* LCD init */ void lcd_init_device(void) { #if CONFIG_LCD == LCD_IPODCOLOR if (ipod_hw_rev == 0x60000) { lcd_type = 0; } else { int gpio_a01, gpio_a04; /* A01 */ gpio_a01 = (inl(0x6000D030) & 0x2) >> 1; /* A04 */ gpio_a04 = (inl(0x6000D030) & 0x10) >> 4; if (((gpio_a01 << 1) | gpio_a04) == 0 || ((gpio_a01 << 1) | gpio_a04) == 2) { lcd_type = 0; } else { lcd_type = 1; } } outl(inl(0x6000d004) | 0x4, 0x6000d004); /* B02 enable */ outl(inl(0x6000d004) | 0x8, 0x6000d004); /* B03 enable */ outl(inl(0x70000084) | 0x2000000, 0x70000084); /* D01 enable */ outl(inl(0x70000080) | 0x2000000, 0x70000080); /* D01 =1 */ outl(inl(0x6000600c) | 0x20000, 0x6000600c); /* PWM enable */ #elif CONFIG_LCD == LCD_IPODNANO /* iPodLinux doesn't appear have any LCD init code for the Nano */ #endif } /*** update functions ***/ /* Performance function that works with an external buffer note that by and bheight are in 4-pixel units! */ void lcd_blit(const fb_data* data, int x, int by, int width, int bheight, int stride) { /* TODO: Implement lcd_blit() */ (void)data; (void)x; (void)by; (void)width; (void)bheight; (void)stride; } #define CSUB_X 2 #define CSUB_Y 2 #define RYFAC (31*257) #define GYFAC (31*257) #define BYFAC (31*257) #define RVFAC 11170 /* 31 * 257 * 1.402 */ #define GVFAC (-5690) /* 31 * 257 * -0.714136 */ #define GUFAC (-2742) /* 31 * 257 * -0.344136 */ #define BUFAC 14118 /* 31 * 257 * 1.772 */ #define ROUNDOFFS (127*257) #define ROUNDOFFSG (63*257) /* Performance function to blit a YUV bitmap directly to the LCD */ void lcd_yuv_blit(unsigned char * const src[3], int src_x, int src_y, int stride, int x, int y, int width, int height) { int h; int y0, x0, y1, x1; width = (width + 1) & ~1; /* calculate the drawing region */ #if CONFIG_LCD == LCD_IPODNANO y0 = x; /* start horiz */ x0 = y; /* start vert */ y1 = (x + width) - 1; /* max horiz */ x1 = (y + height) - 1; /* max vert */ #elif CONFIG_LCD == LCD_IPODCOLOR y0 = y; /* start vert */ x0 = (LCD_WIDTH - 1) - x; /* start horiz */ y1 = (y + height) - 1; /* end vert */ x1 = (x0 - width) + 1; /* end horiz */ #endif /* setup the drawing region */ if (lcd_type == 0) { lcd_cmd_data(0x12, y0); /* start vert */ lcd_cmd_data(0x13, x0); /* start horiz */ lcd_cmd_data(0x15, y1); /* end vert */ lcd_cmd_data(0x16, x1); /* end horiz */ } else { /* swap max horiz < start horiz */ if (y1 < y0) { int t; t = y0; y0 = y1; y1 = t; } /* swap max vert < start vert */ if (x1 < x0) { int t; t = x0; x0 = x1; x1 = t; } /* max horiz << 8 | start horiz */ lcd_cmd_data(LCD_CNTL_HORIZ_RAM_ADDR_POS, (y1 << 8) | y0); /* max vert << 8 | start vert */ lcd_cmd_data(LCD_CNTL_VERT_RAM_ADDR_POS, (x1 << 8) | x0); /* start vert = max vert */ #if CONFIG_LCD == LCD_IPODCOLOR x0 = x1; #endif /* position cursor (set AD0-AD15) */ /* start vert << 8 | start horiz */ lcd_cmd_data(LCD_CNTL_RAM_ADDR_SET, ((x0 << 8) | y0)); /* start drawing */ lcd_send_lo(0x0); lcd_send_lo(LCD_CNTL_WRITE_TO_GRAM); } const int stride_div_csub_x = stride/CSUB_X; h=0; while (1) { /* upsampling, YUV->RGB conversion and reduction to RGB565 in one go */ const unsigned char *ysrc = src[0] + stride * src_y + src_x; const int uvoffset = stride_div_csub_x * (src_y/CSUB_Y) + (src_x/CSUB_X); const unsigned char *usrc = src[1] + uvoffset; const unsigned char *vsrc = src[2] + uvoffset; const unsigned char *row_end = ysrc + width; int y, u, v; int red1, green1, blue1; int red2, green2, blue2; unsigned rbits, gbits, bbits; int rc, gc, bc; int pixels_to_write; fb_data pixel1,pixel2; if (h==0) { while ((inl(0x70008a20) & 0x4000000) == 0); outl(0x0, 0x70008a24); if (height == 0) break; pixels_to_write = (width * height) * 2; h = height; /* calculate how much we can do in one go */ if (pixels_to_write > 0x10000) { h = (0x10000/2) / width; pixels_to_write = (width * h) * 2; } height -= h; outl(0x10000080, 0x70008a20); outl((pixels_to_write - 1) | 0xc0010000, 0x70008a24); outl(0x34000000, 0x70008a20); } do { u = *usrc++ - 128; v = *vsrc++ - 128; rc = RVFAC * v + ROUNDOFFS; gc = GVFAC * v + GUFAC * u + ROUNDOFFSG; bc = BUFAC * u + ROUNDOFFS; /* Pixel 1 */ y = *ysrc++; red1 = RYFAC * y + rc; green1 = GYFAC * y + gc; blue1 = BYFAC * y + bc; /* Pixel 2 */ y = *ysrc++; red2 = RYFAC * y + rc; green2 = GYFAC * y + gc; blue2 = BYFAC * y + bc; /* Since out of bounds errors are relatively rare, we check two pixels at once to see if any components are out of bounds, and then fix whichever is broken. This works due to high values and negative values both becoming larger than the cutoff when casted to unsigned. And ORing them together checks all of them simultaneously. */ if (((unsigned)(red1 | green1 | blue1 | red2 | green2 | blue2)) > (RYFAC*255+ROUNDOFFS)) { if (((unsigned)(red1 | green1 | blue1)) > (RYFAC*255+ROUNDOFFS)) { if ((unsigned)red1 > (RYFAC*255+ROUNDOFFS)) { if (red1 < 0) red1 = 0; else red1 = (RYFAC*255+ROUNDOFFS); } if ((unsigned)green1 > (GYFAC*255+ROUNDOFFSG)) { if (green1 < 0) green1 = 0; else green1 = (GYFAC*255+ROUNDOFFSG); } if ((unsigned)blue1 > (BYFAC*255+ROUNDOFFS)) { if (blue1 < 0) blue1 = 0; else blue1 = (BYFAC*255+ROUNDOFFS); } } if (((unsigned)(red2 | green2 | blue2)) > (RYFAC*255+ROUNDOFFS)) { if ((unsigned)red2 > (RYFAC*255+ROUNDOFFS)) { if (red2 < 0) red2 = 0; else red2 = (RYFAC*255+ROUNDOFFS); } if ((unsigned)green2 > (GYFAC*255+ROUNDOFFSG)) { if (green2 < 0) green2 = 0; else green2 = (GYFAC*255+ROUNDOFFSG); } if ((unsigned)blue2 > (BYFAC*255+ROUNDOFFS)) { if (blue2 < 0) blue2 = 0; else blue2 = (BYFAC*255+ROUNDOFFS); } } } rbits = red1 >> 16 ; gbits = green1 >> 15 ; bbits = blue1 >> 16 ; pixel1 = swap16((rbits << 11) | (gbits << 5) | bbits); rbits = red2 >> 16 ; gbits = green2 >> 15 ; bbits = blue2 >> 16 ; pixel2 = swap16((rbits << 11) | (gbits << 5) | bbits); while ((inl(0x70008a20) & 0x1000000) == 0); /* output 2 pixels */ outl((pixel2<<16)|pixel1, 0x70008b00); } while (ysrc < row_end); src_y++; h--; } while ((inl(0x70008a20) & 0x4000000) == 0); outl(0x0, 0x70008a24); } /* Update a fraction of the display. */ void lcd_update_rect(int x, int y, int width, int height) { int y0, x0, y1, x1; int newx,newwidth; unsigned long *addr = (unsigned long *)lcd_framebuffer; /* Ensure x and width are both even - so we can read 32-bit aligned data from lcd_framebuffer */ newx=x&~1; newwidth=width&~1; if (newx+newwidth < x+width) { newwidth+=2; } x=newx; width=newwidth; /* calculate the drawing region */ #if CONFIG_LCD == LCD_IPODNANO y0 = x; /* start horiz */ x0 = y; /* start vert */ y1 = (x + width) - 1; /* max horiz */ x1 = (y + height) - 1; /* max vert */ #elif CONFIG_LCD == LCD_IPODCOLOR y0 = y; /* start vert */ x0 = (LCD_WIDTH - 1) - x; /* start horiz */ y1 = (y + height) - 1; /* end vert */ x1 = (x0 - width) + 1; /* end horiz */ #endif /* setup the drawing region */ if (lcd_type == 0) { lcd_cmd_data(0x12, y0); /* start vert */ lcd_cmd_data(0x13, x0); /* start horiz */ lcd_cmd_data(0x15, y1); /* end vert */ lcd_cmd_data(0x16, x1); /* end horiz */ } else { /* swap max horiz < start horiz */ if (y1 < y0) { int t; t = y0; y0 = y1; y1 = t; } /* swap max vert < start vert */ if (x1 < x0) { int t; t = x0; x0 = x1; x1 = t; } /* max horiz << 8 | start horiz */ lcd_cmd_data(LCD_CNTL_HORIZ_RAM_ADDR_POS, (y1 << 8) | y0); /* max vert << 8 | start vert */ lcd_cmd_data(LCD_CNTL_VERT_RAM_ADDR_POS, (x1 << 8) | x0); /* start vert = max vert */ #if CONFIG_LCD == LCD_IPODCOLOR x0 = x1; #endif /* position cursor (set AD0-AD15) */ /* start vert << 8 | start horiz */ lcd_cmd_data(LCD_CNTL_RAM_ADDR_SET, ((x0 << 8) | y0)); /* start drawing */ lcd_send_lo(0x0); lcd_send_lo(LCD_CNTL_WRITE_TO_GRAM); } addr = (unsigned long*)&lcd_framebuffer[y][x]; while (height > 0) { int c, r; int h, pixels_to_write; pixels_to_write = (width * height) * 2; h = height; /* calculate how much we can do in one go */ if (pixels_to_write > 0x10000) { h = (0x10000/2) / width; pixels_to_write = (width * h) * 2; } outl(0x10000080, 0x70008a20); outl((pixels_to_write - 1) | 0xc0010000, 0x70008a24); outl(0x34000000, 0x70008a20); /* for each row */ for (r = 0; r < h; r++) { /* for each column */ for (c = 0; c < width; c += 2) { while ((inl(0x70008a20) & 0x1000000) == 0); /* output 2 pixels */ outl(*(addr++), 0x70008b00); } addr += (LCD_WIDTH - width)/2; } while ((inl(0x70008a20) & 0x4000000) == 0); outl(0x0, 0x70008a24); height = height - h; } } /* Update the display. This must be called after all other LCD functions that change the display. */ void lcd_update(void) { lcd_update_rect(0, 0, LCD_WIDTH, LCD_HEIGHT); } #endif