/**
* sdc_set_color_key() - set the transparent color key for SDC graphic plane.
* @mx3fb: mx3fb context.
* @channel: IPU DMAC channel ID.
* @enable: boolean to enable or disable color keyl.
* @color_key: 24-bit RGB color to use as transparent color key.
* @return: 0 on success or negative error code on failure.
*/
static int sdc_set_color_key(struct mx3fb_data *mx3fb, enum ipu_channel channel,
bool enable, uint32_t color_key)
{
uint32_t reg, sdc_conf;
unsigned long lock_flags;
spin_lock_irqsave(&mx3fb->lock, lock_flags);
sdc_conf = mx3fb_read_reg(mx3fb, SDC_COM_CONF);
if (channel == IDMAC_SDC_0)
sdc_conf &= ~SDC_COM_GWSEL;
else
sdc_conf |= SDC_COM_GWSEL;
if (enable) {
reg = mx3fb_read_reg(mx3fb, SDC_GW_CTRL) & 0xFF000000L;
mx3fb_write_reg(mx3fb, reg | (color_key & 0x00FFFFFFL),
SDC_GW_CTRL);
sdc_conf |= SDC_COM_KEY_COLOR_G;
} else {
sdc_conf &= ~SDC_COM_KEY_COLOR_G;
}
mx3fb_write_reg(mx3fb, sdc_conf, SDC_COM_CONF);
spin_unlock_irqrestore(&mx3fb->lock, lock_flags);
return 0;
}
static void sdc_set_brightness(struct mx3fb_data *mx3fb, uint8_t value)
{
dev_dbg(mx3fb->dev, "%s: value = %d\n", __func__, value);
/* This might be board-specific */
mx3fb_write_reg(mx3fb, 0x03000000UL | value << 16, SDC_PWM_CTRL);
return;
}
static void sdc_fb_init(struct mx3fb_info *fbi)
{
struct mx3fb_data *mx3fb = fbi->mx3fb;
uint32_t reg;
reg = mx3fb_read_reg(mx3fb, SDC_COM_CONF);
mx3fb_write_reg(mx3fb, reg | SDC_COM_BG_EN, SDC_COM_CONF);
}
/* Returns enabled flag before uninit */
static uint32_t sdc_fb_uninit(struct mx3fb_info *fbi)
{
struct mx3fb_data *mx3fb = fbi->mx3fb;
uint32_t reg;
reg = mx3fb_read_reg(mx3fb, SDC_COM_CONF);
mx3fb_write_reg(mx3fb, reg & ~SDC_COM_BG_EN, SDC_COM_CONF);
return reg & SDC_COM_BG_EN;
}
/**
* sdc_set_window_pos() - set window position of the respective plane.
* @mx3fb: mx3fb context.
* @channel: IPU DMAC channel ID.
* @x_pos: X coordinate relative to the top left corner to place window at.
* @y_pos: Y coordinate relative to the top left corner to place window at.
* @return: 0 on success or negative error code on failure.
*/
static int sdc_set_window_pos(struct mx3fb_data *mx3fb, enum ipu_channel channel,
int16_t x_pos, int16_t y_pos)
{
if (channel != IDMAC_SDC_0)
return -EINVAL;
x_pos += mx3fb->h_start_width;
y_pos += mx3fb->v_start_width;
mx3fb_write_reg(mx3fb, (x_pos << 16) | y_pos, SDC_BG_POS);
return 0;
}
/**
* sdc_set_global_alpha() - set global alpha blending modes.
* @mx3fb: mx3fb context.
* @enable: boolean to enable or disable global alpha blending. If disabled,
* per pixel blending is used.
* @alpha: global alpha value.
* @return: 0 on success or negative error code on failure.
*/
static int sdc_set_global_alpha(struct mx3fb_data *mx3fb, bool enable, uint8_t alpha)
{
uint32_t reg;
unsigned long lock_flags;
spin_lock_irqsave(&mx3fb->lock, lock_flags);
if (enable) {
reg = mx3fb_read_reg(mx3fb, SDC_GW_CTRL) & 0x00FFFFFFL;
mx3fb_write_reg(mx3fb, reg | ((uint32_t) alpha << 24), SDC_GW_CTRL);
reg = mx3fb_read_reg(mx3fb, SDC_COM_CONF);
mx3fb_write_reg(mx3fb, reg | SDC_COM_GLB_A, SDC_COM_CONF);
} else {
reg = mx3fb_read_reg(mx3fb, SDC_COM_CONF);
mx3fb_write_reg(mx3fb, reg & ~SDC_COM_GLB_A, SDC_COM_CONF);
}
spin_unlock_irqrestore(&mx3fb->lock, lock_flags);
return 0;
}
/**
* sdc_init_panel() - initialize a synchronous LCD panel.
* @mx3fb: mx3fb context.
* @panel: panel type.
* @pixel_clk: desired pixel clock frequency in Hz.
* @width: width of panel in pixels.
* @height: height of panel in pixels.
* @pixel_fmt: pixel format of buffer as FOURCC ASCII code.
* @h_start_width: number of pixel clocks between the HSYNC signal pulse
* and the start of valid data.
* @h_sync_width: width of the HSYNC signal in units of pixel clocks.
* @h_end_width: number of pixel clocks between the end of valid data
* and the HSYNC signal for next line.
* @v_start_width: number of lines between the VSYNC signal pulse and the
* start of valid data.
* @v_sync_width: width of the VSYNC signal in units of lines
* @v_end_width: number of lines between the end of valid data and the
* VSYNC signal for next frame.
* @sig: bitfield of signal polarities for LCD interface.
* @return: 0 on success or negative error code on failure.
*/
static int sdc_init_panel(struct mx3fb_data *mx3fb, enum ipu_panel panel,
uint32_t pixel_clk,
uint16_t width, uint16_t height,
enum pixel_fmt pixel_fmt,
uint16_t h_start_width, uint16_t h_sync_width,
uint16_t h_end_width, uint16_t v_start_width,
uint16_t v_sync_width, uint16_t v_end_width,
struct ipu_di_signal_cfg sig)
{
unsigned long lock_flags;
uint32_t reg;
uint32_t old_conf;
uint32_t div;
struct clk *ipu_clk;
dev_dbg(mx3fb->dev, "panel size = %d x %d", width, height);
if (v_sync_width == 0 || h_sync_width == 0)
return -EINVAL;
/* Init panel size and blanking periods */
reg = ((uint32_t) (h_sync_width - 1) << 26) |
((uint32_t) (width + h_start_width + h_end_width - 1) << 16);
mx3fb_write_reg(mx3fb, reg, SDC_HOR_CONF);
#ifdef DEBUG
printk(KERN_CONT " hor_conf %x,", reg);
#endif
reg = ((uint32_t) (v_sync_width - 1) << 26) | SDC_V_SYNC_WIDTH_L |
((uint32_t) (height + v_start_width + v_end_width - 1) << 16);
mx3fb_write_reg(mx3fb, reg, SDC_VER_CONF);
#ifdef DEBUG
printk(KERN_CONT " ver_conf %x\n", reg);
#endif
mx3fb->h_start_width = h_start_width;
mx3fb->v_start_width = v_start_width;
switch (panel) {
case IPU_PANEL_SHARP_TFT:
mx3fb_write_reg(mx3fb, 0x00FD0102L, SDC_SHARP_CONF_1);
mx3fb_write_reg(mx3fb, 0x00F500F4L, SDC_SHARP_CONF_2);
mx3fb_write_reg(mx3fb, SDC_COM_SHARP | SDC_COM_TFT_COLOR, SDC_COM_CONF);
break;
case IPU_PANEL_TFT:
mx3fb_write_reg(mx3fb, SDC_COM_TFT_COLOR, SDC_COM_CONF);
break;
default:
return -EINVAL;
}
/* Init clocking */
/*
* Calculate divider: fractional part is 4 bits so simply multiple by
* 2^4 to get fractional part, as long as we stay under ~250MHz and on
* i.MX31 it (HSP_CLK) is <= 178MHz. Currently 128.267MHz
*/
ipu_clk = clk_get(mx3fb->dev, NULL);
if (!IS_ERR(ipu_clk)) {
div = clk_get_rate(ipu_clk) * 16 / pixel_clk;
clk_put(ipu_clk);
} else {
div = 0;
}
if (div < 0x40) { /* Divider less than 4 */
dev_dbg(mx3fb->dev,
"InitPanel() - Pixel clock divider less than 4\n");
div = 0x40;
}
dev_dbg(mx3fb->dev, "pixel clk = %u, divider %u.%u\n",
pixel_clk, div >> 4, (div & 7) * 125);
spin_lock_irqsave(&mx3fb->lock, lock_flags);
/*
* DISP3_IF_CLK_DOWN_WR is half the divider value and 2 fraction bits
* fewer. Subtract 1 extra from DISP3_IF_CLK_DOWN_WR based on timing
* debug. DISP3_IF_CLK_UP_WR is 0
*/
mx3fb_write_reg(mx3fb, (((div / 8) - 1) << 22) | div, DI_DISP3_TIME_CONF);
/* DI settings */
old_conf = mx3fb_read_reg(mx3fb, DI_DISP_IF_CONF) & 0x78FFFFFF;
old_conf |= sig.datamask_en << DI_D3_DATAMSK_SHIFT |
sig.clksel_en << DI_D3_CLK_SEL_SHIFT |
sig.clkidle_en << DI_D3_CLK_IDLE_SHIFT;
mx3fb_write_reg(mx3fb, old_conf, DI_DISP_IF_CONF);
old_conf = mx3fb_read_reg(mx3fb, DI_DISP_SIG_POL) & 0xE0FFFFFF;
old_conf |= sig.data_pol << DI_D3_DATA_POL_SHIFT |
sig.clk_pol << DI_D3_CLK_POL_SHIFT |
sig.enable_pol << DI_D3_DRDY_SHARP_POL_SHIFT |
sig.Hsync_pol << DI_D3_HSYNC_POL_SHIFT |
sig.Vsync_pol << DI_D3_VSYNC_POL_SHIFT;
mx3fb_write_reg(mx3fb, old_conf, DI_DISP_SIG_POL);
switch (pixel_fmt) {
case IPU_PIX_FMT_RGB24:
mx3fb_write_reg(mx3fb, di_mappings[0], DI_DISP3_B0_MAP);
mx3fb_write_reg(mx3fb, di_mappings[1], DI_DISP3_B1_MAP);
mx3fb_write_reg(mx3fb, di_mappings[2], DI_DISP3_B2_MAP);
mx3fb_write_reg(mx3fb, mx3fb_read_reg(mx3fb, DI_DISP_ACC_CC) |
((di_mappings[3] - 1) << 12), DI_DISP_ACC_CC);
break;
case IPU_PIX_FMT_RGB666:
mx3fb_write_reg(mx3fb, di_mappings[4], DI_DISP3_B0_MAP);
mx3fb_write_reg(mx3fb, di_mappings[5], DI_DISP3_B1_MAP);
mx3fb_write_reg(mx3fb, di_mappings[6], DI_DISP3_B2_MAP);
mx3fb_write_reg(mx3fb, mx3fb_read_reg(mx3fb, DI_DISP_ACC_CC) |
((di_mappings[7] - 1) << 12), DI_DISP_ACC_CC);
break;
case IPU_PIX_FMT_BGR666:
mx3fb_write_reg(mx3fb, di_mappings[8], DI_DISP3_B0_MAP);
mx3fb_write_reg(mx3fb, di_mappings[9], DI_DISP3_B1_MAP);
mx3fb_write_reg(mx3fb, di_mappings[10], DI_DISP3_B2_MAP);
mx3fb_write_reg(mx3fb, mx3fb_read_reg(mx3fb, DI_DISP_ACC_CC) |
((di_mappings[11] - 1) << 12), DI_DISP_ACC_CC);
break;
default:
mx3fb_write_reg(mx3fb, di_mappings[12], DI_DISP3_B0_MAP);
mx3fb_write_reg(mx3fb, di_mappings[13], DI_DISP3_B1_MAP);
mx3fb_write_reg(mx3fb, di_mappings[14], DI_DISP3_B2_MAP);
mx3fb_write_reg(mx3fb, mx3fb_read_reg(mx3fb, DI_DISP_ACC_CC) |
((di_mappings[15] - 1) << 12), DI_DISP_ACC_CC);
break;
}
spin_unlock_irqrestore(&mx3fb->lock, lock_flags);
dev_dbg(mx3fb->dev, "DI_DISP_IF_CONF = 0x%08X\n",
mx3fb_read_reg(mx3fb, DI_DISP_IF_CONF));
dev_dbg(mx3fb->dev, "DI_DISP_SIG_POL = 0x%08X\n",
mx3fb_read_reg(mx3fb, DI_DISP_SIG_POL));
dev_dbg(mx3fb->dev, "DI_DISP3_TIME_CONF = 0x%08X\n",
mx3fb_read_reg(mx3fb, DI_DISP3_TIME_CONF));
return 0;
}
static void sdc_set_brightness(struct mx3fb_data *mx3fb, uint8_t value)
{
/* This might be board-specific */
mx3fb_write_reg(mx3fb, 0x03000000UL | value << 16, SDC_PWM_CTRL);
return;
}
