/* * Copyright (C) 2008-2009 MontaVista Software Inc. * Copyright (C) 2008-2009 Texas Instruments Inc * * Based on the LCD driver for TI Avalanche processors written by * Ajay Singh and Shalom Hai. * * 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 2 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, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include <linux/module.h> #include <linux/kernel.h> #include <linux/fb.h> #include <linux/dma-mapping.h> #include <linux/device.h> #include <linux/platform_device.h> #include <linux/uaccess.h> #include <linux/pm_runtime.h> #include <linux/interrupt.h> #include <linux/wait.h> #include <linux/clk.h> #include <linux/cpufreq.h> #include <linux/console.h> #include <linux/spinlock.h> #include <linux/slab.h> #include <linux/delay.h> #include <linux/lcm.h> #include <video/da8xx-fb.h> #include <asm/div64.h> #define DRIVER_NAME "da8xx_lcdc" #define LCD_VERSION_1 1 #define LCD_VERSION_2 2 /* LCD Status Register */ #define LCD_END_OF_FRAME1 BIT(9) #define LCD_END_OF_FRAME0 BIT(8) #define LCD_PL_LOAD_DONE BIT(6) #define LCD_FIFO_UNDERFLOW BIT(5) #define LCD_SYNC_LOST BIT(2) #define LCD_FRAME_DONE BIT(0) /* LCD DMA Control Register */ #define LCD_DMA_BURST_SIZE(x) ((x) << 4) #define LCD_DMA_BURST_1 0x0 #define LCD_DMA_BURST_2 0x1 #define LCD_DMA_BURST_4 0x2 #define LCD_DMA_BURST_8 0x3 #define LCD_DMA_BURST_16 0x4 #define LCD_V1_END_OF_FRAME_INT_ENA BIT(2) #define LCD_V2_END_OF_FRAME0_INT_ENA BIT(8) #define LCD_V2_END_OF_FRAME1_INT_ENA BIT(9) #define LCD_DUAL_FRAME_BUFFER_ENABLE BIT(0) /* LCD Control Register */ #define LCD_CLK_DIVISOR(x) ((x) << 8) #define LCD_RASTER_MODE 0x01 /* LCD Raster Control Register */ #define LCD_PALETTE_LOAD_MODE(x) ((x) << 20) #define PALETTE_AND_DATA 0x00 #define PALETTE_ONLY 0x01 #define DATA_ONLY 0x02 #define LCD_MONO_8BIT_MODE BIT(9) #define LCD_RASTER_ORDER BIT(8) #define LCD_TFT_MODE BIT(7) #define LCD_V1_UNDERFLOW_INT_ENA BIT(6) #define LCD_V2_UNDERFLOW_INT_ENA BIT(5) #define LCD_V1_PL_INT_ENA BIT(4) #define LCD_V2_PL_INT_ENA BIT(6) #define LCD_MONOCHROME_MODE BIT(1) #define LCD_RASTER_ENABLE BIT(0) #define LCD_TFT_ALT_ENABLE BIT(23) #define LCD_STN_565_ENABLE BIT(24) #define LCD_V2_DMA_CLK_EN BIT(2) #define LCD_V2_LIDD_CLK_EN BIT(1) #define LCD_V2_CORE_CLK_EN BIT(0) #define LCD_V2_LPP_B10 26 #define LCD_V2_TFT_24BPP_MODE BIT(25) #define LCD_V2_TFT_24BPP_UNPACK BIT(26) /* LCD Raster Timing 2 Register */ #define LCD_AC_BIAS_TRANSITIONS_PER_INT(x) ((x) << 16) #define LCD_AC_BIAS_FREQUENCY(x) ((x) << 8) #define LCD_SYNC_CTRL BIT(25) #define LCD_SYNC_EDGE BIT(24) #define LCD_INVERT_PIXEL_CLOCK BIT(22) #define LCD_INVERT_LINE_CLOCK BIT(21) #define LCD_INVERT_FRAME_CLOCK BIT(20) /* LCD Block */ #define LCD_PID_REG 0x0 #define LCD_CTRL_REG 0x4 #define LCD_STAT_REG 0x8 #define LCD_RASTER_CTRL_REG 0x28 #define LCD_RASTER_TIMING_0_REG 0x2C #define LCD_RASTER_TIMING_1_REG 0x30 #define LCD_RASTER_TIMING_2_REG 0x34 #define LCD_DMA_CTRL_REG 0x40 #define LCD_DMA_FRM_BUF_BASE_ADDR_0_REG 0x44 #define LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG 0x48 #define LCD_DMA_FRM_BUF_BASE_ADDR_1_REG 0x4C #define LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG 0x50 /* Interrupt Registers available only in Version 2 */ #define LCD_RAW_STAT_REG 0x58 #define LCD_MASKED_STAT_REG 0x5c #define LCD_INT_ENABLE_SET_REG 0x60 #define LCD_INT_ENABLE_CLR_REG 0x64 #define LCD_END_OF_INT_IND_REG 0x68 /* Clock registers available only on Version 2 */ #define LCD_CLK_ENABLE_REG 0x6c #define LCD_CLK_RESET_REG 0x70 #define LCD_CLK_MAIN_RESET BIT(3) #define LCD_NUM_BUFFERS 2 #define WSI_TIMEOUT 50 #define PALETTE_SIZE 256 #define LEFT_MARGIN 64 #define RIGHT_MARGIN 64 #define UPPER_MARGIN 32 #define LOWER_MARGIN 32 static void __iomem *da8xx_fb_reg_base; static struct resource *lcdc_regs; static unsigned int lcd_revision; static irq_handler_t lcdc_irq_handler; static wait_queue_head_t frame_done_wq; static int frame_done_flag; static inline unsigned int lcdc_read(unsigned int addr) { return (unsigned int)__raw_readl(da8xx_fb_reg_base + (addr)); } static inline void lcdc_write(unsigned int val, unsigned int addr) { __raw_writel(val, da8xx_fb_reg_base + (addr)); } struct da8xx_fb_par { resource_size_t p_palette_base; unsigned char *v_palette_base; dma_addr_t vram_phys; unsigned long vram_size; void *vram_virt; unsigned int dma_start; unsigned int dma_end; struct clk *lcdc_clk; int irq; unsigned int palette_sz; unsigned int pxl_clk; int blank; wait_queue_head_t vsync_wait; int vsync_flag; int vsync_timeout; spinlock_t lock_for_chan_update; /* * LCDC has 2 ping pong DMA channels, channel 0 * and channel 1. */ unsigned int which_dma_channel_done; #ifdef CONFIG_CPU_FREQ struct notifier_block freq_transition; unsigned int lcd_fck_rate; #endif void (*panel_power_ctrl)(int); u32 pseudo_palette[16]; }; /* Variable Screen Information */ static struct fb_var_screeninfo da8xx_fb_var = { .xoffset = 0, .yoffset = 0, .transp = {0, 0, 0}, .nonstd = 0, .activate = 0, .height = -1, .width = -1, .accel_flags = 0, .left_margin = LEFT_MARGIN, .right_margin = RIGHT_MARGIN, .upper_margin = UPPER_MARGIN, .lower_margin = LOWER_MARGIN, .sync = 0, .vmode = FB_VMODE_NONINTERLACED }; static struct fb_fix_screeninfo da8xx_fb_fix = { .id = "DA8xx FB Drv", .type = FB_TYPE_PACKED_PIXELS, .type_aux = 0, .visual = FB_VISUAL_PSEUDOCOLOR, .xpanstep = 0, .ypanstep = 1, .ywrapstep = 0, .accel = FB_ACCEL_NONE }; static struct fb_videomode known_lcd_panels[] = { /* Sharp LCD035Q3DG01 */ [0] = { .name = "Sharp_LCD035Q3DG01", .xres = 320, .yres = 240, .pixclock = 4608000, .left_margin = 6, .right_margin = 8, .upper_margin = 2, .lower_margin = 2, .hsync_len = 0, .vsync_len = 0, .sync = FB_SYNC_CLK_INVERT | FB_SYNC_HOR_HIGH_ACT | FB_SYNC_VERT_HIGH_ACT, }, /* Sharp LK043T1DG01 */ [1] = { .name = "Sharp_LK043T1DG01", .xres = 480, .yres = 272, .pixclock = 7833600, .left_margin = 2, .right_margin = 2, .upper_margin = 2, .lower_margin = 2, .hsync_len = 41, .vsync_len = 10, .sync = FB_SYNC_HOR_HIGH_ACT | FB_SYNC_VERT_HIGH_ACT, .flag = 0, }, [2] = { /* Hitachi SP10Q010 */ .name = "SP10Q010", .xres = 320, .yres = 240, .pixclock = 7833600, .left_margin = 10, .right_margin = 10, .upper_margin = 10, .lower_margin = 10, .hsync_len = 10, .vsync_len = 10, .sync = FB_SYNC_HOR_HIGH_ACT | FB_SYNC_VERT_HIGH_ACT, .flag = 0, }, }; /* Enable the Raster Engine of the LCD Controller */ static inline void lcd_enable_raster(void) { u32 reg; /* Put LCDC in reset for several cycles */ if (lcd_revision == LCD_VERSION_2) /* Write 1 to reset LCDC */ lcdc_write(LCD_CLK_MAIN_RESET, LCD_CLK_RESET_REG); mdelay(1); /* Bring LCDC out of reset */ if (lcd_revision == LCD_VERSION_2) lcdc_write(0, LCD_CLK_RESET_REG); mdelay(1); /* Above reset sequence doesnot reset register context */ reg = lcdc_read(LCD_RASTER_CTRL_REG); if (!(reg & LCD_RASTER_ENABLE)) lcdc_write(reg | LCD_RASTER_ENABLE, LCD_RASTER_CTRL_REG); } /* Disable the Raster Engine of the LCD Controller */ static inline void lcd_disable_raster(bool wait_for_frame_done) { u32 reg; int ret; reg = lcdc_read(LCD_RASTER_CTRL_REG); if (reg & LCD_RASTER_ENABLE) lcdc_write(reg & ~LCD_RASTER_ENABLE, LCD_RASTER_CTRL_REG); else /* return if already disabled */ return; if ((wait_for_frame_done == true) && (lcd_revision == LCD_VERSION_2)) { frame_done_flag = 0; ret = wait_event_interruptible_timeout(frame_done_wq, frame_done_flag != 0, msecs_to_jiffies(50)); if (ret == 0) pr_err("LCD Controller timed out\n"); } } static void lcd_blit(int load_mode, struct da8xx_fb_par *par) { u32 start; u32 end; u32 reg_ras; u32 reg_dma; u32 reg_int; /* init reg to clear PLM (loading mode) fields */ reg_ras = lcdc_read(LCD_RASTER_CTRL_REG); reg_ras &= ~(3 << 20); reg_dma = lcdc_read(LCD_DMA_CTRL_REG); if (load_mode == LOAD_DATA) { start = par->dma_start; end = par->dma_end; reg_ras |= LCD_PALETTE_LOAD_MODE(DATA_ONLY); if (lcd_revision == LCD_VERSION_1) { reg_dma |= LCD_V1_END_OF_FRAME_INT_ENA; } else { reg_int = lcdc_read(LCD_INT_ENABLE_SET_REG) | LCD_V2_END_OF_FRAME0_INT_ENA | LCD_V2_END_OF_FRAME1_INT_ENA | LCD_FRAME_DONE; lcdc_write(reg_int, LCD_INT_ENABLE_SET_REG); } reg_dma |= LCD_DUAL_FRAME_BUFFER_ENABLE; lcdc_write(start, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(end, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); lcdc_write(start, LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); lcdc_write(end, LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); } else if (load_mode == LOAD_PALETTE) { start = par->p_palette_base; end = start + par->palette_sz - 1; reg_ras |= LCD_PALETTE_LOAD_MODE(PALETTE_ONLY); if (lcd_revision == LCD_VERSION_1) { reg_ras |= LCD_V1_PL_INT_ENA; } else { reg_int = lcdc_read(LCD_INT_ENABLE_SET_REG) | LCD_V2_PL_INT_ENA; lcdc_write(reg_int, LCD_INT_ENABLE_SET_REG); } lcdc_write(start, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(end, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); } lcdc_write(reg_dma, LCD_DMA_CTRL_REG); lcdc_write(reg_ras, LCD_RASTER_CTRL_REG); /* * The Raster enable bit must be set after all other control fields are * set. */ lcd_enable_raster(); } /* Configure the Burst Size and fifo threhold of DMA */ static int lcd_cfg_dma(int burst_size, int fifo_th) { u32 reg; reg = lcdc_read(LCD_DMA_CTRL_REG) & 0x00000001; switch (burst_size) { case 1: reg |= LCD_DMA_BURST_SIZE(LCD_DMA_BURST_1); break; case 2: reg |= LCD_DMA_BURST_SIZE(LCD_DMA_BURST_2); break; case 4: reg |= LCD_DMA_BURST_SIZE(LCD_DMA_BURST_4); break; case 8: reg |= LCD_DMA_BURST_SIZE(LCD_DMA_BURST_8); break; case 16: default: reg |= LCD_DMA_BURST_SIZE(LCD_DMA_BURST_16); break; } reg |= (fifo_th << 8); lcdc_write(reg, LCD_DMA_CTRL_REG); return 0; } static void lcd_cfg_ac_bias(int period, int transitions_per_int) { u32 reg; /* Set the AC Bias Period and Number of Transisitons per Interrupt */ reg = lcdc_read(LCD_RASTER_TIMING_2_REG) & 0xFFF00000; reg |= LCD_AC_BIAS_FREQUENCY(period) | LCD_AC_BIAS_TRANSITIONS_PER_INT(transitions_per_int); lcdc_write(reg, LCD_RASTER_TIMING_2_REG); } static void lcd_cfg_horizontal_sync(int back_porch, int pulse_width, int front_porch) { u32 reg; reg = lcdc_read(LCD_RASTER_TIMING_0_REG) & 0xf; reg |= ((back_porch & 0xff) << 24) | ((front_porch & 0xff) << 16) | ((pulse_width & 0x3f) << 10); lcdc_write(reg, LCD_RASTER_TIMING_0_REG); } static void lcd_cfg_vertical_sync(int back_porch, int pulse_width, int front_porch) { u32 reg; reg = lcdc_read(LCD_RASTER_TIMING_1_REG) & 0x3ff; reg |= ((back_porch & 0xff) << 24) | ((front_porch & 0xff) << 16) | ((pulse_width & 0x3f) << 10); lcdc_write(reg, LCD_RASTER_TIMING_1_REG); } static int lcd_cfg_display(const struct lcd_ctrl_config *cfg, struct fb_videomode *panel) { u32 reg; u32 reg_int; reg = lcdc_read(LCD_RASTER_CTRL_REG) & ~(LCD_TFT_MODE | LCD_MONO_8BIT_MODE | LCD_MONOCHROME_MODE); switch (cfg->panel_shade) { case MONOCHROME: reg |= LCD_MONOCHROME_MODE; if (cfg->mono_8bit_mode) reg |= LCD_MONO_8BIT_MODE; break; case COLOR_ACTIVE: reg |= LCD_TFT_MODE; if (cfg->tft_alt_mode) reg |= LCD_TFT_ALT_ENABLE; break; case COLOR_PASSIVE: /* AC bias applicable only for Pasive panels */ lcd_cfg_ac_bias(cfg->ac_bias, cfg->ac_bias_intrpt); if (cfg->bpp == 12 && cfg->stn_565_mode) reg |= LCD_STN_565_ENABLE; break; default: return -EINVAL; } /* enable additional interrupts here */ if (lcd_revision == LCD_VERSION_1) { reg |= LCD_V1_UNDERFLOW_INT_ENA; } else { reg_int = lcdc_read(LCD_INT_ENABLE_SET_REG) | LCD_V2_UNDERFLOW_INT_ENA; lcdc_write(reg_int, LCD_INT_ENABLE_SET_REG); } lcdc_write(reg, LCD_RASTER_CTRL_REG); reg = lcdc_read(LCD_RASTER_TIMING_2_REG); reg |= LCD_SYNC_CTRL; if (cfg->sync_edge) reg |= LCD_SYNC_EDGE; else reg &= ~LCD_SYNC_EDGE; if (panel->sync & FB_SYNC_HOR_HIGH_ACT) reg |= LCD_INVERT_LINE_CLOCK; else reg &= ~LCD_INVERT_LINE_CLOCK; if (panel->sync & FB_SYNC_VERT_HIGH_ACT) reg |= LCD_INVERT_FRAME_CLOCK; else reg &= ~LCD_INVERT_FRAME_CLOCK; lcdc_write(reg, LCD_RASTER_TIMING_2_REG); return 0; } static int lcd_cfg_frame_buffer(struct da8xx_fb_par *par, u32 width, u32 height, u32 bpp, u32 raster_order) { u32 reg; if (bpp > 16 && lcd_revision == LCD_VERSION_1) return -EINVAL; /* Set the Panel Width */ /* Pixels per line = (PPL + 1)*16 */ if (lcd_revision == LCD_VERSION_1) { /* * 0x3F in bits 4..9 gives max horizontal resolution = 1024 * pixels. */ width &= 0x3f0; } else { /* * 0x7F in bits 4..10 gives max horizontal resolution = 2048 * pixels. */ width &= 0x7f0; } reg = lcdc_read(LCD_RASTER_TIMING_0_REG); reg &= 0xfffffc00; if (lcd_revision == LCD_VERSION_1) { reg |= ((width >> 4) - 1) << 4; } else { width = (width >> 4) - 1; reg |= ((width & 0x3f) << 4) | ((width & 0x40) >> 3); } lcdc_write(reg, LCD_RASTER_TIMING_0_REG); /* Set the Panel Height */ /* Set bits 9:0 of Lines Per Pixel */ reg = lcdc_read(LCD_RASTER_TIMING_1_REG); reg = ((height - 1) & 0x3ff) | (reg & 0xfffffc00); lcdc_write(reg, LCD_RASTER_TIMING_1_REG); /* Set bit 10 of Lines Per Pixel */ if (lcd_revision == LCD_VERSION_2) { reg = lcdc_read(LCD_RASTER_TIMING_2_REG); reg |= ((height - 1) & 0x400) << 16; lcdc_write(reg, LCD_RASTER_TIMING_2_REG); } /* Set the Raster Order of the Frame Buffer */ reg = lcdc_read(LCD_RASTER_CTRL_REG) & ~(1 << 8); if (raster_order) reg |= LCD_RASTER_ORDER; par->palette_sz = 16 * 2; switch (bpp) { case 1: case 2: case 4: case 16: break; case 24: reg |= LCD_V2_TFT_24BPP_MODE; case 32: reg |= LCD_V2_TFT_24BPP_UNPACK; break; case 8: par->palette_sz = 256 * 2; break; default: return -EINVAL; } lcdc_write(reg, LCD_RASTER_CTRL_REG); return 0; } #define CNVT_TOHW(val, width) ((((val) << (width)) + 0x7FFF - (val)) >> 16) static int fb_setcolreg(unsigned regno, unsigned red, unsigned green, unsigned blue, unsigned transp, struct fb_info *info) { struct da8xx_fb_par *par = info->par; unsigned short *palette = (unsigned short *) par->v_palette_base; u_short pal; int update_hw = 0; if (regno > 255) return 1; if (info->fix.visual == FB_VISUAL_DIRECTCOLOR) return 1; if (info->var.bits_per_pixel > 16 && lcd_revision == LCD_VERSION_1) return -EINVAL; switch (info->fix.visual) { case FB_VISUAL_TRUECOLOR: red = CNVT_TOHW(red, info->var.red.length); green = CNVT_TOHW(green, info->var.green.length); blue = CNVT_TOHW(blue, info->var.blue.length); break; case FB_VISUAL_PSEUDOCOLOR: switch (info->var.bits_per_pixel) { case 4: if (regno > 15) return -EINVAL; if (info->var.grayscale) { pal = regno; } else { red >>= 4; green >>= 8; blue >>= 12; pal = red & 0x0f00; pal |= green & 0x00f0; pal |= blue & 0x000f; } if (regno == 0) pal |= 0x2000; palette[regno] = pal; break; case 8: red >>= 4; green >>= 8; blue >>= 12; pal = (red & 0x0f00); pal |= (green & 0x00f0); pal |= (blue & 0x000f); if (palette[regno] != pal) { update_hw = 1; palette[regno] = pal; } break; } break; } /* Truecolor has hardware independent palette */ if (info->fix.visual == FB_VISUAL_TRUECOLOR) { u32 v; if (regno > 15) return -EINVAL; v = (red << info->var.red.offset) | (green << info->var.green.offset) | (blue << info->var.blue.offset); switch (info->var.bits_per_pixel) { case 16: ((u16 *) (info->pseudo_palette))[regno] = v; break; case 24: case 32: ((u32 *) (info->pseudo_palette))[regno] = v; break; } if (palette[0] != 0x4000) { update_hw = 1; palette[0] = 0x4000; } } /* Update the palette in the h/w as needed. */ if (update_hw) lcd_blit(LOAD_PALETTE, par); return 0; } #undef CNVT_TOHW static void lcd_reset(struct da8xx_fb_par *par) { /* Disable the Raster if previously Enabled */ lcd_disable_raster(false); /* DMA has to be disabled */ lcdc_write(0, LCD_DMA_CTRL_REG); lcdc_write(0, LCD_RASTER_CTRL_REG); if (lcd_revision == LCD_VERSION_2) { lcdc_write(0, LCD_INT_ENABLE_SET_REG); /* Write 1 to reset */ lcdc_write(LCD_CLK_MAIN_RESET, LCD_CLK_RESET_REG); lcdc_write(0, LCD_CLK_RESET_REG); } } static void lcd_calc_clk_divider(struct da8xx_fb_par *par) { unsigned int lcd_clk, div; lcd_clk = clk_get_rate(par->lcdc_clk); div = lcd_clk / par->pxl_clk; /* Configure the LCD clock divisor. */ lcdc_write(LCD_CLK_DIVISOR(div) | (LCD_RASTER_MODE & 0x1), LCD_CTRL_REG); if (lcd_revision == LCD_VERSION_2) lcdc_write(LCD_V2_DMA_CLK_EN | LCD_V2_LIDD_CLK_EN | LCD_V2_CORE_CLK_EN, LCD_CLK_ENABLE_REG); } static int lcd_init(struct da8xx_fb_par *par, const struct lcd_ctrl_config *cfg, struct fb_videomode *panel) { u32 bpp; int ret = 0; lcd_reset(par); /* Calculate the divider */ lcd_calc_clk_divider(par); if (panel->sync & FB_SYNC_CLK_INVERT) lcdc_write((lcdc_read(LCD_RASTER_TIMING_2_REG) | LCD_INVERT_PIXEL_CLOCK), LCD_RASTER_TIMING_2_REG); else lcdc_write((lcdc_read(LCD_RASTER_TIMING_2_REG) & ~LCD_INVERT_PIXEL_CLOCK), LCD_RASTER_TIMING_2_REG); /* Configure the DMA burst size and fifo threshold. */ ret = lcd_cfg_dma(cfg->dma_burst_sz, cfg->fifo_th); if (ret < 0) return ret; /* Configure the vertical and horizontal sync properties. */ lcd_cfg_vertical_sync(panel->lower_margin, panel->vsync_len, panel->upper_margin); lcd_cfg_horizontal_sync(panel->right_margin, panel->hsync_len, panel->left_margin); /* Configure for disply */ ret = lcd_cfg_display(cfg, panel); if (ret < 0) return ret; bpp = cfg->bpp; if (bpp == 12) bpp = 16; ret = lcd_cfg_frame_buffer(par, (unsigned int)panel->xres, (unsigned int)panel->yres, bpp, cfg->raster_order); if (ret < 0) return ret; /* Configure FDD */ lcdc_write((lcdc_read(LCD_RASTER_CTRL_REG) & 0xfff00fff) | (cfg->fdd << 12), LCD_RASTER_CTRL_REG); return 0; } /* IRQ handler for version 2 of LCDC */ static irqreturn_t lcdc_irq_handler_rev02(int irq, void *arg) { struct da8xx_fb_par *par = arg; u32 stat = lcdc_read(LCD_MASKED_STAT_REG); if ((stat & LCD_SYNC_LOST) && (stat & LCD_FIFO_UNDERFLOW)) { lcd_disable_raster(false); lcdc_write(stat, LCD_MASKED_STAT_REG); lcd_enable_raster(); } else if (stat & LCD_PL_LOAD_DONE) { /* * Must disable raster before changing state of any control bit. * And also must be disabled before clearing the PL loading * interrupt via the following write to the status register. If * this is done after then one gets multiple PL done interrupts. */ lcd_disable_raster(false); lcdc_write(stat, LCD_MASKED_STAT_REG); /* Disable PL completion interrupt */ lcdc_write(LCD_V2_PL_INT_ENA, LCD_INT_ENABLE_CLR_REG); /* Setup and start data loading mode */ lcd_blit(LOAD_DATA, par); } else { lcdc_write(stat, LCD_MASKED_STAT_REG); if (stat & LCD_END_OF_FRAME0) { par->which_dma_channel_done = 0; lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); par->vsync_flag = 1; wake_up_interruptible(&par->vsync_wait); } if (stat & LCD_END_OF_FRAME1) { par->which_dma_channel_done = 1; lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); par->vsync_flag = 1; wake_up_interruptible(&par->vsync_wait); } /* Set only when controller is disabled and at the end of * active frame */ if (stat & BIT(0)) { frame_done_flag = 1; wake_up_interruptible(&frame_done_wq); } } lcdc_write(0, LCD_END_OF_INT_IND_REG); return IRQ_HANDLED; } /* IRQ handler for version 1 LCDC */ static irqreturn_t lcdc_irq_handler_rev01(int irq, void *arg) { struct da8xx_fb_par *par = arg; u32 stat = lcdc_read(LCD_STAT_REG); u32 reg_ras; if ((stat & LCD_SYNC_LOST) && (stat & LCD_FIFO_UNDERFLOW)) { lcd_disable_raster(false); lcdc_write(stat, LCD_STAT_REG); lcd_enable_raster(); } else if (stat & LCD_PL_LOAD_DONE) { /* * Must disable raster before changing state of any control bit. * And also must be disabled before clearing the PL loading * interrupt via the following write to the status register. If * this is done after then one gets multiple PL done interrupts. */ lcd_disable_raster(false); lcdc_write(stat, LCD_STAT_REG); /* Disable PL completion inerrupt */ reg_ras = lcdc_read(LCD_RASTER_CTRL_REG); reg_ras &= ~LCD_V1_PL_INT_ENA; lcdc_write(reg_ras, LCD_RASTER_CTRL_REG); /* Setup and start data loading mode */ lcd_blit(LOAD_DATA, par); } else { lcdc_write(stat, LCD_STAT_REG); if (stat & LCD_END_OF_FRAME0) { par->which_dma_channel_done = 0; lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); par->vsync_flag = 1; wake_up_interruptible(&par->vsync_wait); } if (stat & LCD_END_OF_FRAME1) { par->which_dma_channel_done = 1; lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); par->vsync_flag = 1; wake_up_interruptible(&par->vsync_wait); } } return IRQ_HANDLED; } static int fb_check_var(struct fb_var_screeninfo *var, struct fb_info *info) { int err = 0; if (var->bits_per_pixel > 16 && lcd_revision == LCD_VERSION_1) return -EINVAL; switch (var->bits_per_pixel) { case 1: case 8: var->red.offset = 0; var->red.length = 8; var->green.offset = 0; var->green.length = 8; var->blue.offset = 0; var->blue.length = 8; var->transp.offset = 0; var->transp.length = 0; var->nonstd = 0; break; case 4: var->red.offset = 0; var->red.length = 4; var->green.offset = 0; var->green.length = 4; var->blue.offset = 0; var->blue.length = 4; var->transp.offset = 0; var->transp.length = 0; var->nonstd = FB_NONSTD_REV_PIX_IN_B; break; case 16: /* RGB 565 */ var->red.offset = 11; var->red.length = 5; var->green.offset = 5; var->green.length = 6; var->blue.offset = 0; var->blue.length = 5; var->transp.offset = 0; var->transp.length = 0; var->nonstd = 0; break; case 24: var->red.offset = 16; var->red.length = 8; var->green.offset = 8; var->green.length = 8; var->blue.offset = 0; var->blue.length = 8; var->nonstd = 0; break; case 32: var->transp.offset = 24; var->transp.length = 8; var->red.offset = 16; var->red.length = 8; var->green.offset = 8; var->green.length = 8; var->blue.offset = 0; var->blue.length = 8; var->nonstd = 0; break; default: err = -EINVAL; } var->red.msb_right = 0; var->green.msb_right = 0; var->blue.msb_right = 0; var->transp.msb_right = 0; return err; } #ifdef CONFIG_CPU_FREQ static int lcd_da8xx_cpufreq_transition(struct notifier_block *nb, unsigned long val, void *data) { struct da8xx_fb_par *par; par = container_of(nb, struct da8xx_fb_par, freq_transition); if (val == CPUFREQ_POSTCHANGE) { if (par->lcd_fck_rate != clk_get_rate(par->lcdc_clk)) { par->lcd_fck_rate = clk_get_rate(par->lcdc_clk); lcd_disable_raster(true); lcd_calc_clk_divider(par); if (par->blank == FB_BLANK_UNBLANK) lcd_enable_raster(); } } return 0; } static inline int lcd_da8xx_cpufreq_register(struct da8xx_fb_par *par) { par->freq_transition.notifier_call = lcd_da8xx_cpufreq_transition; return cpufreq_register_notifier(&par->freq_transition, CPUFREQ_TRANSITION_NOTIFIER); } static inline void lcd_da8xx_cpufreq_deregister(struct da8xx_fb_par *par) { cpufreq_unregister_notifier(&par->freq_transition, CPUFREQ_TRANSITION_NOTIFIER); } #endif static int fb_remove(struct platform_device *dev) { struct fb_info *info = dev_get_drvdata(&dev->dev); if (info) { struct da8xx_fb_par *par = info->par; #ifdef CONFIG_CPU_FREQ lcd_da8xx_cpufreq_deregister(par); #endif if (par->panel_power_ctrl) par->panel_power_ctrl(0); lcd_disable_raster(true); lcdc_write(0, LCD_RASTER_CTRL_REG); /* disable DMA */ lcdc_write(0, LCD_DMA_CTRL_REG); unregister_framebuffer(info); fb_dealloc_cmap(&info->cmap); dma_free_coherent(NULL, PALETTE_SIZE, par->v_palette_base, par->p_palette_base); dma_free_coherent(NULL, par->vram_size, par->vram_virt, par->vram_phys); free_irq(par->irq, par); pm_runtime_put_sync(&dev->dev); pm_runtime_disable(&dev->dev); framebuffer_release(info); iounmap(da8xx_fb_reg_base); release_mem_region(lcdc_regs->start, resource_size(lcdc_regs)); } return 0; } /* * Function to wait for vertical sync which for this LCD peripheral * translates into waiting for the current raster frame to complete. */ static int fb_wait_for_vsync(struct fb_info *info) { struct da8xx_fb_par *par = info->par; int ret; /* * Set flag to 0 and wait for isr to set to 1. It would seem there is a * race condition here where the ISR could have occurred just before or * just after this set. But since we are just coarsely waiting for * a frame to complete then that's OK. i.e. if the frame completed * just before this code executed then we have to wait another full * frame time but there is no way to avoid such a situation. On the * other hand if the frame completed just after then we don't need * to wait long at all. Either way we are guaranteed to return to the * user immediately after a frame completion which is all that is * required. */ par->vsync_flag = 0; ret = wait_event_interruptible_timeout(par->vsync_wait, par->vsync_flag != 0, par->vsync_timeout); if (ret < 0) return ret; if (ret == 0) return -ETIMEDOUT; return 0; } static int fb_ioctl(struct fb_info *info, unsigned int cmd, unsigned long arg) { struct lcd_sync_arg sync_arg; switch (cmd) { case FBIOGET_CONTRAST: case FBIOPUT_CONTRAST: case FBIGET_BRIGHTNESS: case FBIPUT_BRIGHTNESS: case FBIGET_COLOR: case FBIPUT_COLOR: return -ENOTTY; case FBIPUT_HSYNC: if (copy_from_user(&sync_arg, (char *)arg, sizeof(struct lcd_sync_arg))) return -EFAULT; lcd_cfg_horizontal_sync(sync_arg.back_porch, sync_arg.pulse_width, sync_arg.front_porch); break; case FBIPUT_VSYNC: if (copy_from_user(&sync_arg, (char *)arg, sizeof(struct lcd_sync_arg))) return -EFAULT; lcd_cfg_vertical_sync(sync_arg.back_porch, sync_arg.pulse_width, sync_arg.front_porch); break; case FBIO_WAITFORVSYNC: return fb_wait_for_vsync(info); default: return -EINVAL; } return 0; } static int cfb_blank(int blank, struct fb_info *info) { struct da8xx_fb_par *par = info->par; int ret = 0; if (par->blank == blank) return 0; par->blank = blank; switch (blank) { case FB_BLANK_UNBLANK: lcd_enable_raster(); if (par->panel_power_ctrl) par->panel_power_ctrl(1); break; case FB_BLANK_NORMAL: case FB_BLANK_VSYNC_SUSPEND: case FB_BLANK_HSYNC_SUSPEND: case FB_BLANK_POWERDOWN: if (par->panel_power_ctrl) par->panel_power_ctrl(0); lcd_disable_raster(true); break; default: ret = -EINVAL; } return ret; } /* * Set new x,y offsets in the virtual display for the visible area and switch * to the new mode. */ static int da8xx_pan_display(struct fb_var_screeninfo *var, struct fb_info *fbi) { int ret = 0; struct fb_var_screeninfo new_var; struct da8xx_fb_par *par = fbi->par; struct fb_fix_screeninfo *fix = &fbi->fix; unsigned int end; unsigned int start; unsigned long irq_flags; if (var->xoffset != fbi->var.xoffset || var->yoffset != fbi->var.yoffset) { memcpy(&new_var, &fbi->var, sizeof(new_var)); new_var.xoffset = var->xoffset; new_var.yoffset = var->yoffset; if (fb_check_var(&new_var, fbi)) ret = -EINVAL; else { memcpy(&fbi->var, &new_var, sizeof(new_var)); start = fix->smem_start + new_var.yoffset * fix->line_length + new_var.xoffset * fbi->var.bits_per_pixel / 8; end = start + fbi->var.yres * fix->line_length - 1; par->dma_start = start; par->dma_end = end; spin_lock_irqsave(&par->lock_for_chan_update, irq_flags); if (par->which_dma_channel_done == 0) { lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); } else if (par->which_dma_channel_done == 1) { lcdc_write(par->dma_start, LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); lcdc_write(par->dma_end, LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); } spin_unlock_irqrestore(&par->lock_for_chan_update, irq_flags); } } return ret; } static struct fb_ops da8xx_fb_ops = { .owner = THIS_MODULE, .fb_check_var = fb_check_var, .fb_setcolreg = fb_setcolreg, .fb_pan_display = da8xx_pan_display, .fb_ioctl = fb_ioctl, .fb_fillrect = cfb_fillrect, .fb_copyarea = cfb_copyarea, .fb_imageblit = cfb_imageblit, .fb_blank = cfb_blank, }; /* Calculate and return pixel clock period in pico seconds */ static unsigned int da8xxfb_pixel_clk_period(struct da8xx_fb_par *par) { unsigned int lcd_clk, div; unsigned int configured_pix_clk; unsigned long long pix_clk_period_picosec = 1000000000000ULL; lcd_clk = clk_get_rate(par->lcdc_clk); div = lcd_clk / par->pxl_clk; configured_pix_clk = (lcd_clk / div); do_div(pix_clk_period_picosec, configured_pix_clk); return pix_clk_period_picosec; } static int fb_probe(struct platform_device *device) { struct da8xx_lcdc_platform_data *fb_pdata = device->dev.platform_data; struct lcd_ctrl_config *lcd_cfg; struct fb_videomode *lcdc_info; struct fb_info *da8xx_fb_info; struct clk *fb_clk = NULL; struct da8xx_fb_par *par; resource_size_t len; int ret, i; unsigned long ulcm; if (fb_pdata == NULL) { dev_err(&device->dev, "Can not get platform data\n"); return -ENOENT; } lcdc_regs = platform_get_resource(device, IORESOURCE_MEM, 0); if (!lcdc_regs) { dev_err(&device->dev, "Can not get memory resource for LCD controller\n"); return -ENOENT; } len = resource_size(lcdc_regs); lcdc_regs = request_mem_region(lcdc_regs->start, len, lcdc_regs->name); if (!lcdc_regs) return -EBUSY; da8xx_fb_reg_base = ioremap(lcdc_regs->start, len); if (!da8xx_fb_reg_base) { ret = -EBUSY; goto err_request_mem; } fb_clk = clk_get(&device->dev, "fck"); if (IS_ERR(fb_clk)) { dev_err(&device->dev, "Can not get device clock\n"); ret = -ENODEV; goto err_ioremap; } pm_runtime_enable(&device->dev); pm_runtime_get_sync(&device->dev); /* Determine LCD IP Version */ switch (lcdc_read(LCD_PID_REG)) { case 0x4C100102: lcd_revision = LCD_VERSION_1; break; case 0x4F200800: case 0x4F201000: lcd_revision = LCD_VERSION_2; break; default: dev_warn(&device->dev, "Unknown PID Reg value 0x%x, " "defaulting to LCD revision 1\n", lcdc_read(LCD_PID_REG)); lcd_revision = LCD_VERSION_1; break; } for (i = 0, lcdc_info = known_lcd_panels; i < ARRAY_SIZE(known_lcd_panels); i++, lcdc_info++) { if (strcmp(fb_pdata->type, lcdc_info->name) == 0) break; } if (i == ARRAY_SIZE(known_lcd_panels)) { dev_err(&device->dev, "GLCD: No valid panel found\n"); ret = -ENODEV; goto err_pm_runtime_disable; } else dev_info(&device->dev, "GLCD: Found %s panel\n", fb_pdata->type); lcd_cfg = (struct lcd_ctrl_config *)fb_pdata->controller_data; da8xx_fb_info = framebuffer_alloc(sizeof(struct da8xx_fb_par), &device->dev); if (!da8xx_fb_info) { dev_dbg(&device->dev, "Memory allocation failed for fb_info\n"); ret = -ENOMEM; goto err_pm_runtime_disable; } par = da8xx_fb_info->par; par->lcdc_clk = fb_clk; #ifdef CONFIG_CPU_FREQ par->lcd_fck_rate = clk_get_rate(fb_clk); #endif par->pxl_clk = lcdc_info->pixclock; if (fb_pdata->panel_power_ctrl) { par->panel_power_ctrl = fb_pdata->panel_power_ctrl; par->panel_power_ctrl(1); } if (lcd_init(par, lcd_cfg, lcdc_info) < 0) { dev_err(&device->dev, "lcd_init failed\n"); ret = -EFAULT; goto err_release_fb; } /* allocate frame buffer */ par->vram_size = lcdc_info->xres * lcdc_info->yres * lcd_cfg->bpp; ulcm = lcm((lcdc_info->xres * lcd_cfg->bpp)/8, PAGE_SIZE); par->vram_size = roundup(par->vram_size/8, ulcm); par->vram_size = par->vram_size * LCD_NUM_BUFFERS; par->vram_virt = dma_alloc_coherent(NULL, par->vram_size, (resource_size_t *) &par->vram_phys, GFP_KERNEL | GFP_DMA); if (!par->vram_virt) { dev_err(&device->dev, "GLCD: kmalloc for frame buffer failed\n"); ret = -EINVAL; goto err_release_fb; } da8xx_fb_info->screen_base = (char __iomem *) par->vram_virt; da8xx_fb_fix.smem_start = par->vram_phys; da8xx_fb_fix.smem_len = par->vram_size; da8xx_fb_fix.line_length = (lcdc_info->xres * lcd_cfg->bpp) / 8; par->dma_start = par->vram_phys; par->dma_end = par->dma_start + lcdc_info->yres * da8xx_fb_fix.line_length - 1; /* allocate palette buffer */ par->v_palette_base = dma_alloc_coherent(NULL, PALETTE_SIZE, (resource_size_t *) &par->p_palette_base, GFP_KERNEL | GFP_DMA); if (!par->v_palette_base) { dev_err(&device->dev, "GLCD: kmalloc for palette buffer failed\n"); ret = -EINVAL; goto err_release_fb_mem; } memset(par->v_palette_base, 0, PALETTE_SIZE); par->irq = platform_get_irq(device, 0); if (par->irq < 0) { ret = -ENOENT; goto err_release_pl_mem; } /* Initialize par */ da8xx_fb_info->var.bits_per_pixel = lcd_cfg->bpp; da8xx_fb_var.xres = lcdc_info->xres; da8xx_fb_var.xres_virtual = lcdc_info->xres; da8xx_fb_var.yres = lcdc_info->yres; da8xx_fb_var.yres_virtual = lcdc_info->yres * LCD_NUM_BUFFERS; da8xx_fb_var.grayscale = lcd_cfg->panel_shade == MONOCHROME ? 1 : 0; da8xx_fb_var.bits_per_pixel = lcd_cfg->bpp; da8xx_fb_var.hsync_len = lcdc_info->hsync_len; da8xx_fb_var.vsync_len = lcdc_info->vsync_len; da8xx_fb_var.right_margin = lcdc_info->right_margin; da8xx_fb_var.left_margin = lcdc_info->left_margin; da8xx_fb_var.lower_margin = lcdc_info->lower_margin; da8xx_fb_var.upper_margin = lcdc_info->upper_margin; da8xx_fb_var.pixclock = da8xxfb_pixel_clk_period(par); /* Initialize fbinfo */ da8xx_fb_info->flags = FBINFO_FLAG_DEFAULT; da8xx_fb_info->fix = da8xx_fb_fix; da8xx_fb_info->var = da8xx_fb_var; da8xx_fb_info->fbops = &da8xx_fb_ops; da8xx_fb_info->pseudo_palette = par->pseudo_palette; da8xx_fb_info->fix.visual = (da8xx_fb_info->var.bits_per_pixel <= 8) ? FB_VISUAL_PSEUDOCOLOR : FB_VISUAL_TRUECOLOR; ret = fb_alloc_cmap(&da8xx_fb_info->cmap, PALETTE_SIZE, 0); if (ret) goto err_release_pl_mem; da8xx_fb_info->cmap.len = par->palette_sz; /* initialize var_screeninfo */ da8xx_fb_var.activate = FB_ACTIVATE_FORCE; fb_set_var(da8xx_fb_info, &da8xx_fb_var); dev_set_drvdata(&device->dev, da8xx_fb_info); /* initialize the vsync wait queue */ init_waitqueue_head(&par->vsync_wait); par->vsync_timeout = HZ / 5; par->which_dma_channel_done = -1; spin_lock_init(&par->lock_for_chan_update); /* Register the Frame Buffer */ if (register_framebuffer(da8xx_fb_info) < 0) { dev_err(&device->dev, "GLCD: Frame Buffer Registration Failed!\n"); ret = -EINVAL; goto err_dealloc_cmap; } #ifdef CONFIG_CPU_FREQ ret = lcd_da8xx_cpufreq_register(par); if (ret) { dev_err(&device->dev, "failed to register cpufreq\n"); goto err_cpu_freq; } #endif if (lcd_revision == LCD_VERSION_1) lcdc_irq_handler = lcdc_irq_handler_rev01; else { init_waitqueue_head(&frame_done_wq); lcdc_irq_handler = lcdc_irq_handler_rev02; } ret = request_irq(par->irq, lcdc_irq_handler, 0, DRIVER_NAME, par); if (ret) goto irq_freq; return 0; irq_freq: #ifdef CONFIG_CPU_FREQ lcd_da8xx_cpufreq_deregister(par); err_cpu_freq: #endif unregister_framebuffer(da8xx_fb_info); err_dealloc_cmap: fb_dealloc_cmap(&da8xx_fb_info->cmap); err_release_pl_mem: dma_free_coherent(NULL, PALETTE_SIZE, par->v_palette_base, par->p_palette_base); err_release_fb_mem: dma_free_coherent(NULL, par->vram_size, par->vram_virt, par->vram_phys); err_release_fb: framebuffer_release(da8xx_fb_info); err_pm_runtime_disable: pm_runtime_put_sync(&device->dev); pm_runtime_disable(&device->dev); err_ioremap: iounmap(da8xx_fb_reg_base); err_request_mem: release_mem_region(lcdc_regs->start, len); return ret; } #ifdef CONFIG_PM struct lcdc_context { u32 clk_enable; u32 ctrl; u32 dma_ctrl; u32 raster_timing_0; u32 raster_timing_1; u32 raster_timing_2; u32 int_enable_set; u32 dma_frm_buf_base_addr_0; u32 dma_frm_buf_ceiling_addr_0; u32 dma_frm_buf_base_addr_1; u32 dma_frm_buf_ceiling_addr_1; u32 raster_ctrl; } reg_context; static void lcd_context_save(void) { if (lcd_revision == LCD_VERSION_2) { reg_context.clk_enable = lcdc_read(LCD_CLK_ENABLE_REG); reg_context.int_enable_set = lcdc_read(LCD_INT_ENABLE_SET_REG); } reg_context.ctrl = lcdc_read(LCD_CTRL_REG); reg_context.dma_ctrl = lcdc_read(LCD_DMA_CTRL_REG); reg_context.raster_timing_0 = lcdc_read(LCD_RASTER_TIMING_0_REG); reg_context.raster_timing_1 = lcdc_read(LCD_RASTER_TIMING_1_REG); reg_context.raster_timing_2 = lcdc_read(LCD_RASTER_TIMING_2_REG); reg_context.dma_frm_buf_base_addr_0 = lcdc_read(LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); reg_context.dma_frm_buf_ceiling_addr_0 = lcdc_read(LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); reg_context.dma_frm_buf_base_addr_1 = lcdc_read(LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); reg_context.dma_frm_buf_ceiling_addr_1 = lcdc_read(LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); reg_context.raster_ctrl = lcdc_read(LCD_RASTER_CTRL_REG); return; } static void lcd_context_restore(void) { if (lcd_revision == LCD_VERSION_2) { lcdc_write(reg_context.clk_enable, LCD_CLK_ENABLE_REG); lcdc_write(reg_context.int_enable_set, LCD_INT_ENABLE_SET_REG); } lcdc_write(reg_context.ctrl, LCD_CTRL_REG); lcdc_write(reg_context.dma_ctrl, LCD_DMA_CTRL_REG); lcdc_write(reg_context.raster_timing_0, LCD_RASTER_TIMING_0_REG); lcdc_write(reg_context.raster_timing_1, LCD_RASTER_TIMING_1_REG); lcdc_write(reg_context.raster_timing_2, LCD_RASTER_TIMING_2_REG); lcdc_write(reg_context.dma_frm_buf_base_addr_0, LCD_DMA_FRM_BUF_BASE_ADDR_0_REG); lcdc_write(reg_context.dma_frm_buf_ceiling_addr_0, LCD_DMA_FRM_BUF_CEILING_ADDR_0_REG); lcdc_write(reg_context.dma_frm_buf_base_addr_1, LCD_DMA_FRM_BUF_BASE_ADDR_1_REG); lcdc_write(reg_context.dma_frm_buf_ceiling_addr_1, LCD_DMA_FRM_BUF_CEILING_ADDR_1_REG); lcdc_write(reg_context.raster_ctrl, LCD_RASTER_CTRL_REG); return; } static int fb_suspend(struct platform_device *dev, pm_message_t state) { struct fb_info *info = platform_get_drvdata(dev); struct da8xx_fb_par *par = info->par; console_lock(); if (par->panel_power_ctrl) par->panel_power_ctrl(0); fb_set_suspend(info, 1); lcd_disable_raster(true); lcd_context_save(); pm_runtime_put_sync(&dev->dev); console_unlock(); return 0; } static int fb_resume(struct platform_device *dev) { struct fb_info *info = platform_get_drvdata(dev); struct da8xx_fb_par *par = info->par; console_lock(); pm_runtime_get_sync(&dev->dev); lcd_context_restore(); if (par->blank == FB_BLANK_UNBLANK) { lcd_enable_raster(); if (par->panel_power_ctrl) par->panel_power_ctrl(1); } fb_set_suspend(info, 0); console_unlock(); return 0; } #else #define fb_suspend NULL #define fb_resume NULL #endif static struct platform_driver da8xx_fb_driver = { .probe = fb_probe, .remove = fb_remove, .suspend = fb_suspend, .resume = fb_resume, .driver = { .name = DRIVER_NAME, .owner = THIS_MODULE, }, }; static int __init da8xx_fb_init(void) { return platform_driver_register(&da8xx_fb_driver); } static void __exit da8xx_fb_cleanup(void) { platform_driver_unregister(&da8xx_fb_driver); } module_init(da8xx_fb_init); module_exit(da8xx_fb_cleanup); MODULE_DESCRIPTION("Framebuffer driver for TI da8xx/omap-l1xx"); MODULE_AUTHOR("Texas Instruments"); MODULE_LICENSE("GPL");