/*
* Initializes the NFC hardware.
*/
int mxs_nand_init(struct mxs_nand_info *info)
{
struct mxs_gpmi_regs *gpmi_regs =
(struct mxs_gpmi_regs *)MXS_GPMI_BASE;
struct mxs_bch_regs *bch_regs =
(struct mxs_bch_regs *)MXS_BCH_BASE;
int i = 0, j, ret = 0;
info->desc = malloc(sizeof(struct mxs_dma_desc *) *
MXS_NAND_DMA_DESCRIPTOR_COUNT);
if (!info->desc) {
ret = -ENOMEM;
goto err1;
}
/* Allocate the DMA descriptors. */
for (i = 0; i < MXS_NAND_DMA_DESCRIPTOR_COUNT; i++) {
info->desc[i] = mxs_dma_desc_alloc();
if (!info->desc[i]) {
ret = -ENOMEM;
goto err2;
}
}
/* Init the DMA controller. */
mxs_dma_init();
for (j = MXS_DMA_CHANNEL_AHB_APBH_GPMI0;
j <= MXS_DMA_CHANNEL_AHB_APBH_GPMI7; j++) {
ret = mxs_dma_init_channel(j);
if (ret)
goto err3;
}
/* Reset the GPMI block. */
mxs_reset_block(&gpmi_regs->hw_gpmi_ctrl0_reg);
mxs_reset_block(&bch_regs->hw_bch_ctrl_reg);
/*
* Choose NAND mode, set IRQ polarity, disable write protection and
* select BCH ECC.
*/
clrsetbits_le32(&gpmi_regs->hw_gpmi_ctrl1,
GPMI_CTRL1_GPMI_MODE,
GPMI_CTRL1_ATA_IRQRDY_POLARITY | GPMI_CTRL1_DEV_RESET |
GPMI_CTRL1_BCH_MODE);
return 0;
err3:
for (--j; j >= MXS_DMA_CHANNEL_AHB_APBH_GPMI0; j--)
mxs_dma_release(j);
err2:
for (--i; i >= 0; i--)
mxs_dma_desc_free(info->desc[i]);
free(info->desc);
err1:
if (ret == -ENOMEM)
printf("MXS NAND: Unable to allocate DMA descriptors\n");
return ret;
}
void __init avic_init_irq(void __iomem *base, int nr_irqs)
{
int i;
g_icoll_base = base;
mxs_reset_block(base + HW_ICOLL_CTRL, 0);
for (i = 0; i < nr_irqs; i++) {
__raw_writel(0, g_icoll_base + HW_ICOLL_INTERRUPTn(i));
set_irq_chip(i, &icoll_chip);
set_irq_handler(i, handle_level_irq);
set_irq_flags(i, IRQF_VALID | IRQF_PROBE);
}
__raw_writel(BF_ICOLL_LEVELACK_IRQLEVELACK
(BV_ICOLL_LEVELACK_IRQLEVELACK__LEVEL0),
g_icoll_base + HW_ICOLL_LEVELACK);
__raw_writel(BF_ICOLL_LEVELACK_IRQLEVELACK
(BV_ICOLL_LEVELACK_IRQLEVELACK__LEVEL1),
g_icoll_base + HW_ICOLL_LEVELACK);
__raw_writel(BF_ICOLL_LEVELACK_IRQLEVELACK
(BV_ICOLL_LEVELACK_IRQLEVELACK__LEVEL2),
g_icoll_base + HW_ICOLL_LEVELACK);
__raw_writel(BF_ICOLL_LEVELACK_IRQLEVELACK
(BV_ICOLL_LEVELACK_IRQLEVELACK__LEVEL3),
g_icoll_base + HW_ICOLL_LEVELACK);
__raw_writel(0, g_icoll_base + HW_ICOLL_VECTOR);
/* Barrier */
(void)__raw_readl(g_icoll_base + HW_ICOLL_STAT);
}
static int mxsmmc_init(struct mmc *mmc)
{
struct mxsmmc_priv *priv = (struct mxsmmc_priv *)mmc->priv;
struct mxs_ssp_regs *ssp_regs = priv->regs;
/* Reset SSP */
mxs_reset_block(&ssp_regs->hw_ssp_ctrl0_reg);
/* Reconfigure the SSP block for MMC operation */
writel(SSP_CTRL1_SSP_MODE_SD_MMC |
SSP_CTRL1_WORD_LENGTH_EIGHT_BITS |
SSP_CTRL1_DMA_ENABLE |
SSP_CTRL1_POLARITY |
SSP_CTRL1_RECV_TIMEOUT_IRQ_EN |
SSP_CTRL1_DATA_CRC_IRQ_EN |
SSP_CTRL1_DATA_TIMEOUT_IRQ_EN |
SSP_CTRL1_RESP_TIMEOUT_IRQ_EN |
SSP_CTRL1_RESP_ERR_IRQ_EN,
&ssp_regs->hw_ssp_ctrl1_set);
/* Set initial bit clock 400 KHz */
mxs_set_ssp_busclock(priv->id, 400);
/* Send initial 74 clock cycles (185 us @ 400 KHz)*/
writel(SSP_CMD0_CONT_CLKING_EN, &ssp_regs->hw_ssp_cmd0_set);
udelay(200);
writel(SSP_CMD0_CONT_CLKING_EN, &ssp_regs->hw_ssp_cmd0_clr);
return 0;
}
static void mx23_mem_init(void)
{
/*
* Reset/ungate the EMI block. This is essential, otherwise the system
* suffers from memory instability. This thing is mx23 specific and is
* no longer present on mx28.
*/
mxs_reset_block((struct mxs_register_32 *)MXS_EMI_BASE);
mx23_mem_setup_vddmem();
/*
* Configure the DRAM registers
*/
/* Clear START and SREFRESH bit from DRAM_CTL8 */
clrbits_le32(MXS_DRAM_BASE + 0x20, (1 << 16) | (1 << 8));
initialize_dram_values();
/* Set START bit in DRAM_CTL8 */
setbits_le32(MXS_DRAM_BASE + 0x20, 1 << 16);
clrbits_le32(MXS_DRAM_BASE + 0x40, 1 << 17);
early_delay(20000);
/* Adjust EMI port priority. */
clrsetbits_le32(0x80020000, 0x1f << 16, 0x2);
early_delay(20000);
setbits_le32(MXS_DRAM_BASE + 0x40, 1 << 19);
setbits_le32(MXS_DRAM_BASE + 0x40, 1 << 11);
}
static int stmp3xxx_rtc_resume(struct platform_device *dev)
{
struct stmp3xxx_rtc_data *rtc_data = platform_get_drvdata(dev);
mxs_reset_block(rtc_data->io);
writel(STMP3XXX_RTC_PERSISTENT0_ALARM_EN |
STMP3XXX_RTC_PERSISTENT0_ALARM_WAKE_EN |
STMP3XXX_RTC_PERSISTENT0_ALARM_WAKE,
rtc_data->io + STMP3XXX_RTC_PERSISTENT0_CLR);
return 0;
}
void __init icoll_init_irq(void)
{
int i;
mxs_reset_block(icoll_base + HW_ICOLL_CTRL);
for (i = 0; i < MXS_INTERNAL_IRQS; i++) {
irq_set_chip_and_handler(i, &mxs_icoll_chip, handle_level_irq);
set_irq_flags(i, IRQF_VALID);
}
}
void __init mxs_timer_init(int irq)
{
struct clk *timer_clk;
timer_clk = clk_get_sys("timrot", NULL);
if (IS_ERR(timer_clk)) {
pr_err("%s: failed to get clk\n", __func__);
return;
}
clk_prepare_enable(timer_clk);
/*
* Initialize timers to a known state
*/
mxs_reset_block(mxs_timrot_base + HW_TIMROT_ROTCTRL);
/* get timrot version */
timrot_major_version = __raw_readl(mxs_timrot_base +
(cpu_is_mx23() ? MX23_TIMROT_VERSION_OFFSET :
MX28_TIMROT_VERSION_OFFSET));
timrot_major_version >>= BP_TIMROT_MAJOR_VERSION;
/* one for clock_event */
__raw_writel((timrot_is_v1() ?
BV_TIMROTv1_TIMCTRLn_SELECT__32KHZ_XTAL :
BV_TIMROTv2_TIMCTRLn_SELECT__32KHZ_XTAL) |
BM_TIMROT_TIMCTRLn_UPDATE |
BM_TIMROT_TIMCTRLn_IRQ_EN,
mxs_timrot_base + HW_TIMROT_TIMCTRLn(0));
/* another for clocksource */
__raw_writel((timrot_is_v1() ?
BV_TIMROTv1_TIMCTRLn_SELECT__32KHZ_XTAL :
BV_TIMROTv2_TIMCTRLn_SELECT__32KHZ_XTAL) |
BM_TIMROT_TIMCTRLn_RELOAD,
mxs_timrot_base + HW_TIMROT_TIMCTRLn(1));
/* set clocksource timer fixed count to the maximum */
if (timrot_is_v1())
__raw_writel(0xffff,
mxs_timrot_base + HW_TIMROT_TIMCOUNTn(1));
else
__raw_writel(0xffffffff,
mxs_timrot_base + HW_TIMROT_FIXED_COUNTn(1));
/* init and register the timer to the framework */
mxs_clocksource_init(timer_clk);
mxs_clockevent_init(timer_clk);
/* Make irqs happen */
setup_irq(irq, &mxs_timer_irq);
}
/*
* Nominally, the purpose of this function is to look for or create the bad
* block table. In fact, since the we call this function at the very end of
* the initialization process started by nand_scan(), and we doesn't have a
* more formal mechanism, we "hook" this function to continue init process.
*
* At this point, the physical NAND Flash chips have been identified and
* counted, so we know the physical geometry. This enables us to make some
* important configuration decisions.
*
* The return value of this function propogates directly back to this driver's
* call to nand_scan(). Anything other than zero will cause this driver to
* tear everything down and declare failure.
*/
static int mxs_nand_scan_bbt(struct mtd_info *mtd)
{
struct nand_chip *nand = mtd->priv;
struct mxs_nand_info *nand_info = nand->priv;
struct mxs_bch_regs *bch_regs = (struct mxs_bch_regs *)MXS_BCH_BASE;
uint32_t tmp;
/* Configure BCH and set NFC geometry */
mxs_reset_block(&bch_regs->hw_bch_ctrl_reg);
/* Configure layout 0 */
tmp = (mxs_nand_ecc_chunk_cnt(mtd->writesize) - 1)
<< BCH_FLASHLAYOUT0_NBLOCKS_OFFSET;
tmp |= MXS_NAND_METADATA_SIZE << BCH_FLASHLAYOUT0_META_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT0_ECC0_OFFSET;
tmp |= MXS_NAND_CHUNK_DATA_CHUNK_SIZE
>> MXS_NAND_CHUNK_DATA_CHUNK_SIZE_SHIFT;
writel(tmp, &bch_regs->hw_bch_flash0layout0);
tmp = (mtd->writesize + mtd->oobsize)
<< BCH_FLASHLAYOUT1_PAGE_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT1_ECCN_OFFSET;
tmp |= MXS_NAND_CHUNK_DATA_CHUNK_SIZE
>> MXS_NAND_CHUNK_DATA_CHUNK_SIZE_SHIFT;
writel(tmp, &bch_regs->hw_bch_flash0layout1);
/* Set *all* chip selects to use layout 0 */
writel(0, &bch_regs->hw_bch_layoutselect);
/* Enable BCH complete interrupt */
writel(BCH_CTRL_COMPLETE_IRQ_EN, &bch_regs->hw_bch_ctrl_set);
/* Hook some operations at the MTD level. */
if (mtd->_read_oob != mxs_nand_hook_read_oob) {
nand_info->hooked_read_oob = mtd->_read_oob;
mtd->_read_oob = mxs_nand_hook_read_oob;
}
if (mtd->_write_oob != mxs_nand_hook_write_oob) {
nand_info->hooked_write_oob = mtd->_write_oob;
mtd->_write_oob = mxs_nand_hook_write_oob;
}
if (mtd->_block_markbad != mxs_nand_hook_block_markbad) {
nand_info->hooked_block_markbad = mtd->_block_markbad;
mtd->_block_markbad = mxs_nand_hook_block_markbad;
}
/* We use the reference implementation for bad block management. */
return nand_default_bbt(mtd);
}
void rtc_reset(void)
{
struct mxs_rtc_regs *rtc_regs = (struct mxs_rtc_regs *)MXS_RTC_BASE;
int ret;
/* Set time to 1970-01-01 */
mxs_rtc_set_time(0);
/* Reset the RTC block */
ret = mxs_reset_block(&rtc_regs->hw_rtc_ctrl_reg);
if (ret)
printf("MXS RTC: Block reset timeout\n");
}
void __init icoll_init_irq(void)
{
int i;
/*
* Interrupt Collector reset, which initializes the priority
* for each irq to level 0.
*/
mxs_reset_block(icoll_base + HW_ICOLL_CTRL);
for (i = 0; i < MXS_INTERNAL_IRQS; i++) {
set_irq_chip(i, &mxs_icoll_chip);
set_irq_handler(i, handle_level_irq);
set_irq_flags(i, IRQF_VALID);
}
}
static int mxs_nand_gpmi_init(void)
{
int ret;
/* Reset the GPMI block. */
ret = mxs_reset_block(&gpmi_regs->hw_gpmi_ctrl0_reg);
if (ret)
return ret;
/*
* Choose NAND mode, set IRQ polarity, disable write protection and
* select BCH ECC.
*/
clrsetbits_le32(&gpmi_regs->hw_gpmi_ctrl1,
GPMI_CTRL1_GPMI_MODE,
GPMI_CTRL1_ATA_IRQRDY_POLARITY | GPMI_CTRL1_DEV_RESET |
GPMI_CTRL1_BCH_MODE);
writel(0x500 << 16, &gpmi_regs->hw_gpmi_timing1);
return 0;
}
int timer_init(void)
{
struct mxs_timrot_regs *timrot_regs =
(struct mxs_timrot_regs *)MXS_TIMROT_BASE;
/* Reset Timers and Rotary Encoder module */
mxs_reset_block(&timrot_regs->hw_timrot_rotctrl_reg);
/* Set fixed_count to 0 */
writel(0, &timrot_regs->hw_timrot_fixed_count0);
/* Set UPDATE bit and 1Khz frequency */
writel(TIMROT_TIMCTRLn_UPDATE | TIMROT_TIMCTRLn_RELOAD |
TIMROT_TIMCTRLn_SELECT_1KHZ_XTAL,
&timrot_regs->hw_timrot_timctrl0);
#ifndef DEBUG_TIMER_WRAP
/* Set fixed_count to maximum value */
writel(TIMER_LOAD_VAL, &timrot_regs->hw_timrot_fixed_count0);
#else
/* Set fixed_count so that the counter will wrap after 20 seconds */
writel(20 * MXS_INCREMENTER_HZ,
&timrot_regs->hw_timrot_fixed_count0);
gd->arch.lastinc = TIMER_LOAD_VAL - 20 * MXS_INCREMENTER_HZ;
#endif
#ifdef DEBUG_TIMER_WRAP
/* Make the usec counter roll over 30 seconds after startup */
writel(-30000000, MXS_HW_DIGCTL_MICROSECONDS);
#endif
writel(TIMROT_TIMCTRLn_UPDATE,
&timrot_regs->hw_timrot_timctrl0_clr);
#ifdef DEBUG_TIMER_WRAP
/* Set fixed_count to maximal value for subsequent loads */
writel(TIMER_LOAD_VAL, &timrot_regs->hw_timrot_fixed_count0);
#endif
gd->arch.timer_rate_hz = MXS_INCREMENTER_HZ;
gd->arch.tbl = TIMER_START;
gd->arch.tbu = 0;
return 0;
}
static int init_bl(struct mxs_platform_bl_data *data)
{
int ret = 0;
pwm_clk = clk_get(NULL, "pwm");
if (IS_ERR(pwm_clk)) {
ret = PTR_ERR(pwm_clk);
return ret;
}
clk_enable(pwm_clk);
mxs_reset_block(REGS_PWM_BASE, 1);
__raw_writel(BF_PWM_ACTIVEn_INACTIVE(400) |
BF_PWM_ACTIVEn_ACTIVE(0),
REGS_PWM_BASE + HW_PWM_ACTIVEn(4));
__raw_writel(BF_PWM_PERIODn_CDIV(6) | /* divide by 64 */
BF_PWM_PERIODn_INACTIVE_STATE(2) | /* low */
BF_PWM_PERIODn_ACTIVE_STATE(3) | /* high */
BF_PWM_PERIODn_PERIOD(599),
REGS_PWM_BASE + HW_PWM_PERIODn(4));
__raw_writel(BM_PWM_CTRL_PWM4_ENABLE, REGS_PWM_BASE + HW_PWM_CTRL_SET);
__raw_writel(BF_PINCTRL_DOUT3_DOUT(1 << 30), REGS_PINCTRL_BASE + HW_PINCTRL_DOUT3_SET);
return 0;
}
static int mxsmmc_init(struct mmc *mmc)
{
struct mxsmmc_priv *priv = (struct mxsmmc_priv *)mmc->priv;
struct mxs_ssp_regs *ssp_regs = priv->regs;
/* Reset SSP */
mxs_reset_block(&ssp_regs->hw_ssp_ctrl0_reg);
/* 8 bits word length in MMC mode */
clrsetbits_le32(&ssp_regs->hw_ssp_ctrl1,
SSP_CTRL1_SSP_MODE_MASK | SSP_CTRL1_WORD_LENGTH_MASK |
SSP_CTRL1_DMA_ENABLE,
SSP_CTRL1_SSP_MODE_SD_MMC | SSP_CTRL1_WORD_LENGTH_EIGHT_BITS);
/* Set initial bit clock 400 KHz */
mx28_set_ssp_busclock(priv->id, 400);
/* Send initial 74 clock cycles (185 us @ 400 KHz)*/
writel(SSP_CMD0_CONT_CLKING_EN, &ssp_regs->hw_ssp_cmd0_set);
udelay(200);
writel(SSP_CMD0_CONT_CLKING_EN, &ssp_regs->hw_ssp_cmd0_clr);
return 0;
}
void video_hw_init(void *lcdbase)
{
int ret;
unsigned int div = 0, best = 0, pix_clk;
u32 frac1;
const unsigned long lcd_clk = 480000000;
u32 lcd_ctrl = LCD_CTRL_DEFAULT | LCDIF_CTRL_RUN;
u32 lcd_ctrl1 = LCD_CTRL1_DEFAULT, lcd_ctrl2 = LCD_CTRL2_DEFAULT;
u32 lcd_vdctrl0 = LCD_VDCTRL0_DEFAULT;
u32 lcd_vdctrl1 = LCD_VDCTRL1_DEFAULT;
u32 lcd_vdctrl2 = LCD_VDCTRL2_DEFAULT;
u32 lcd_vdctrl3 = LCD_VDCTRL3_DEFAULT;
u32 lcd_vdctrl4 = LCD_VDCTRL4_DEFAULT;
struct mxs_clkctrl_regs *clk_regs = (void *)MXS_CLKCTRL_BASE;
char buf1[16], buf2[16];
/* pixel format in memory */
switch (color_depth) {
case 8:
lcd_ctrl |= LCDIF_CTRL_WORD_LENGTH_8BIT;
lcd_ctrl1 |= LCDIF_CTRL1_BYTE_PACKING_FORMAT(1);
break;
case 16:
lcd_ctrl |= LCDIF_CTRL_WORD_LENGTH_16BIT;
lcd_ctrl1 |= LCDIF_CTRL1_BYTE_PACKING_FORMAT(3);
break;
case 18:
lcd_ctrl |= LCDIF_CTRL_WORD_LENGTH_18BIT;
lcd_ctrl1 |= LCDIF_CTRL1_BYTE_PACKING_FORMAT(7);
break;
case 24:
lcd_ctrl |= LCDIF_CTRL_WORD_LENGTH_24BIT;
lcd_ctrl1 |= LCDIF_CTRL1_BYTE_PACKING_FORMAT(7);
break;
default:
printf("Invalid bpp: %d\n", color_depth);
return;
}
/* pixel format on the LCD data pins */
switch (pix_fmt) {
case PIX_FMT_RGB332:
lcd_ctrl |= LCDIF_CTRL_LCD_DATABUS_WIDTH_8BIT;
break;
case PIX_FMT_RGB565:
lcd_ctrl |= LCDIF_CTRL_LCD_DATABUS_WIDTH_16BIT;
break;
case PIX_FMT_BGR666:
lcd_ctrl |= 1 << LCDIF_CTRL_INPUT_DATA_SWIZZLE_OFFSET;
/* fallthru */
case PIX_FMT_RGB666:
lcd_ctrl |= LCDIF_CTRL_LCD_DATABUS_WIDTH_18BIT;
break;
case PIX_FMT_BGR24:
lcd_ctrl |= 1 << LCDIF_CTRL_INPUT_DATA_SWIZZLE_OFFSET;
/* fallthru */
case PIX_FMT_RGB24:
lcd_ctrl |= LCDIF_CTRL_LCD_DATABUS_WIDTH_24BIT;
break;
default:
printf("Invalid pixel format: %c%c%c%c\n", fourcc_str(pix_fmt));
return;
}
pix_clk = PICOS2KHZ(mxsfb_var.pixclock);
debug("designated pix_clk: %sMHz\n", strmhz(buf1, pix_clk * 1000));
for (frac1 = 18; frac1 < 36; frac1++) {
static unsigned int err = ~0;
unsigned long clk = lcd_clk / 1000 * 18 / frac1;
unsigned int d = (clk + pix_clk - 1) / pix_clk;
unsigned int diff = abs(clk / d - pix_clk);
debug("frac1=%u div=%u lcd_clk=%-8sMHz pix_clk=%-8sMHz diff=%u err=%u\n",
frac1, d, strmhz(buf1, clk * 1000), strmhz(buf2, clk * 1000 / d),
diff, err);
if (clk < pix_clk)
break;
if (d > 255)
continue;
if (diff < err) {
best = frac1;
div = d;
err = diff;
if (err == 0)
break;
}
}
if (div == 0) {
printf("Requested pixel clock %sMHz out of range\n",
strmhz(buf1, pix_clk * 1000));
return;
}
debug("div=%lu(%u*%u/18) for pixel clock %sMHz with base clock %sMHz\n",
lcd_clk / pix_clk / 1000, best, div,
strmhz(buf1, lcd_clk / div * 18 / best),
strmhz(buf2, lcd_clk));
frac1 = (readl(&clk_regs->hw_clkctrl_frac1_reg) & ~0xff) | best;
writel(frac1, &clk_regs->hw_clkctrl_frac1_reg);
writel(1 << 14, &clk_regs->hw_clkctrl_clkseq_clr);
/* enable LCD clk and fractional divider */
writel(div, &clk_regs->hw_clkctrl_lcdif_reg);
while (readl(&clk_regs->hw_clkctrl_lcdif_reg) & (1 << 29))
;
ret = mxs_reset_block(&lcd_regs->hw_lcdif_ctrl_reg);
if (ret) {
printf("Failed to reset LCD controller: LCDIF_CTRL: %08x CLKCTRL_LCDIF: %08x\n",
readl(&lcd_regs->hw_lcdif_ctrl_reg),
readl(&clk_regs->hw_clkctrl_lcdif_reg));
return;
}
if (mxsfb_var.sync & FB_SYNC_HOR_HIGH_ACT)
lcd_vdctrl0 |= LCDIF_VDCTRL0_HSYNC_POL;
if (mxsfb_var.sync & FB_SYNC_VERT_HIGH_ACT)
lcd_vdctrl0 |= LCDIF_VDCTRL0_HSYNC_POL;
if (mxsfb_var.sync & FB_SYNC_DATA_ENABLE_HIGH_ACT)
lcd_vdctrl0 |= LCDIF_VDCTRL0_ENABLE_POL;
if (mxsfb_var.sync & FB_SYNC_DOTCLK_FALLING_ACT)
lcd_vdctrl0 |= LCDIF_VDCTRL0_DOTCLK_POL;
lcd_vdctrl0 |= LCDIF_VDCTRL0_VSYNC_PULSE_WIDTH(mxsfb_var.vsync_len);
lcd_vdctrl1 |= LCDIF_VDCTRL1_VSYNC_PERIOD(mxsfb_var.vsync_len +
mxsfb_var.upper_margin +
mxsfb_var.lower_margin +
mxsfb_var.yres);
lcd_vdctrl2 |= LCDIF_VDCTRL2_HSYNC_PULSE_WIDTH(mxsfb_var.hsync_len);
lcd_vdctrl2 |= LCDIF_VDCTRL2_HSYNC_PERIOD(mxsfb_var.hsync_len +
mxsfb_var.left_margin +
mxsfb_var.right_margin +
mxsfb_var.xres);
lcd_vdctrl3 |= LCDIF_VDCTRL3_HORIZONTAL_WAIT_CNT(mxsfb_var.left_margin +
mxsfb_var.hsync_len);
lcd_vdctrl3 |= LCDIF_VDCTRL3_VERTICAL_WAIT_CNT(mxsfb_var.upper_margin +
mxsfb_var.vsync_len);
lcd_vdctrl4 |= LCDIF_VDCTRL4_DOTCLK_H_VALID_DATA_CNT(mxsfb_var.xres);
writel((u32)lcdbase, &lcd_regs->hw_lcdif_next_buf_reg);
writel(LCDIF_TRANSFER_COUNT_H_COUNT(mxsfb_var.xres) |
LCDIF_TRANSFER_COUNT_V_COUNT(mxsfb_var.yres),
&lcd_regs->hw_lcdif_transfer_count_reg);
writel(lcd_vdctrl0, &lcd_regs->hw_lcdif_vdctrl0_reg);
writel(lcd_vdctrl1, &lcd_regs->hw_lcdif_vdctrl1_reg);
writel(lcd_vdctrl2, &lcd_regs->hw_lcdif_vdctrl2_reg);
writel(lcd_vdctrl3, &lcd_regs->hw_lcdif_vdctrl3_reg);
writel(lcd_vdctrl4, &lcd_regs->hw_lcdif_vdctrl4_reg);
writel(lcd_ctrl1, &lcd_regs->hw_lcdif_ctrl1_reg);
writel(lcd_ctrl2, &lcd_regs->hw_lcdif_ctrl2_reg);
writel(lcd_ctrl, &lcd_regs->hw_lcdif_ctrl_reg);
debug("mxsfb framebuffer driver initialized\n");
}
static int __devinit mxs_pwm_led_probe(struct platform_device *pdev)
{
struct mxs_pwm_leds_plat_data *plat_data;
struct resource *res;
struct led_classdev *led;
unsigned int pwmn;
int leds_in_use = 0, rc = 0;
int i;
plat_data = (struct mxs_pwm_leds_plat_data *)pdev->dev.platform_data;
if (plat_data == NULL)
return -ENODEV;
res = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (res == NULL)
return -ENODEV;
leds.base = (unsigned int)IO_ADDRESS(res->start);
mxs_reset_block((void __iomem *)leds.base, 1);
leds.led_num = plat_data->num;
if (leds.led_num <= 0 || leds.led_num > CONFIG_MXS_PWM_CHANNELS)
return -EFAULT;
leds.leds = plat_data->leds;
if (leds.leds == NULL)
return -EFAULT;
leds.pwm_clk = clk_get(&pdev->dev, "pwm");
if (IS_ERR(leds.pwm_clk)) {
rc = PTR_ERR(leds.pwm_clk);
return rc;
}
clk_enable(leds.pwm_clk);
for (i = 0; i < leds.led_num; i++) {
pwmn = leds.leds[i].pwm;
if (pwmn >= CONFIG_MXS_PWM_CHANNELS) {
dev_err(&pdev->dev,
"[led-pwm%d]:PWM %d doesn't exist\n",
i, pwmn);
continue;
}
led = &(leds.leds[i].dev);
led->name = leds.leds[i].name;
/*Foxconn, KingsChen, MKD, 20130924 {*/
led->brightness = MAX_LEVEL;
led->max_brightness=MAX_LEVEL;
MKD_DEFAULT_LEVEL = MAX_LEVEL;
//led->brightness = LED_HALF;
/*Foxconn, KingsChen, MKD, 20130924 }*/
led->flags = 0;
led->brightness_set = mxs_pwm_led_brightness_set;
led->default_trigger = 0;
rc = led_classdev_register(&pdev->dev, led);
if (rc < 0) {
dev_err(&pdev->dev,
"Unable to register LED device %d (err=%d)\n",
i, rc);
continue;
}
leds_in_use++;
/* Set default brightness */
/*Foxconn, KingsChen, MKD, 20130924 {*/
mxs_pwm_led_brightness_set(led, MAX_LEVEL);
//mxs_pwm_led_brightness_set(led, LED_HALF);
/*Foxconn, KingsChen, MKD, 20130924 }*/
}
/*Foxconn, KingsChen, MKD, 20131119 {*/
led_probe_done=1;
/*Foxconn, KingsChen, MKD, 20131119 }*/
if (leds_in_use == 0) {
dev_info(&pdev->dev, "No PWM LEDs available\n");
clk_disable(leds.pwm_clk);
clk_put(leds.pwm_clk);
return -ENODEV;
}
return 0;
}
/*
* Nominally, the purpose of this function is to look for or create the bad
* block table. In fact, since the we call this function at the very end of
* the initialization process started by nand_scan(), and we don't have a
* more formal mechanism, we "hook" this function to continue init process.
*
* At this point, the physical NAND Flash chips have been identified and
* counted, so we know the physical geometry. This enables us to make some
* important configuration decisions.
*
* The return value of this function propogates directly back to this driver's
* call to nand_scan(). Anything other than zero will cause this driver to
* tear everything down and declare failure.
*/
static int mxs_nand_scan_bbt(struct mtd_info *mtd)
{
struct nand_chip *nand = mtd->priv;
struct mxs_nand_info *nand_info = nand->priv;
uint32_t tmp;
/* Configure BCH and set NFC geometry */
if (readl(&bch_regs->hw_bch_ctrl_reg) &
(BCH_CTRL_SFTRST | BCH_CTRL_CLKGATE))
/* When booting from NAND the BCH engine will already
* be operational and obviously does not like being reset here.
* There will be occasional read errors upon boot when this
* reset is done.
*/
mxs_reset_block(&bch_regs->hw_bch_ctrl_reg);
readl(&bch_regs->hw_bch_ctrl_reg);
debug("mtd->writesize=%d\n", mtd->writesize);
debug("mtd->oobsize=%d\n", mtd->oobsize);
debug("ecc_strength=%d\n", mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize));
/* Configure layout 0 */
tmp = (mxs_nand_ecc_chunk_cnt(mtd) - 1)
<< BCH_FLASHLAYOUT0_NBLOCKS_OFFSET;
tmp |= MXS_NAND_METADATA_SIZE << BCH_FLASHLAYOUT0_META_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT0_ECC0_OFFSET;
tmp |= MXS_NAND_CHUNK_DATA_CHUNK_SIZE;
writel(tmp, &bch_regs->hw_bch_flash0layout0);
tmp = (mtd->writesize + mtd->oobsize)
<< BCH_FLASHLAYOUT1_PAGE_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT1_ECCN_OFFSET;
tmp |= MXS_NAND_CHUNK_DATA_CHUNK_SIZE;
writel(tmp, &bch_regs->hw_bch_flash0layout1);
/* Set *all* chip selects to use layout 0 */
writel(0, &bch_regs->hw_bch_layoutselect);
/* Enable BCH complete interrupt */
writel(BCH_CTRL_COMPLETE_IRQ_EN, &bch_regs->hw_bch_ctrl_set);
/* Hook some operations at the MTD level. */
if (mtd->read_oob != mxs_nand_hook_read_oob) {
nand_info->hooked_read_oob = mtd->read_oob;
mtd->read_oob = mxs_nand_hook_read_oob;
}
if (mtd->write_oob != mxs_nand_hook_write_oob) {
nand_info->hooked_write_oob = mtd->write_oob;
mtd->write_oob = mxs_nand_hook_write_oob;
}
if (mtd->block_markbad != mxs_nand_hook_block_markbad) {
nand_info->hooked_block_markbad = mtd->block_markbad;
mtd->block_markbad = mxs_nand_hook_block_markbad;
}
/* We use the reference implementation for bad block management. */
return nand_default_bbt(mtd);
}
static int stmp3xxx_rtc_probe(struct platform_device *pdev)
{
struct stmp3xxx_rtc_data *rtc_data;
struct resource *r;
int err;
rtc_data = kzalloc(sizeof *rtc_data, GFP_KERNEL);
if (!rtc_data)
return -ENOMEM;
r = platform_get_resource(pdev, IORESOURCE_MEM, 0);
if (!r) {
dev_err(&pdev->dev, "failed to get resource\n");
err = -ENXIO;
goto out_free;
}
rtc_data->io = ioremap(r->start, resource_size(r));
if (!rtc_data->io) {
dev_err(&pdev->dev, "ioremap failed\n");
err = -EIO;
goto out_free;
}
rtc_data->irq_alarm = platform_get_irq(pdev, 0);
if (!(readl(STMP3XXX_RTC_STAT + rtc_data->io) &
STMP3XXX_RTC_STAT_RTC_PRESENT)) {
dev_err(&pdev->dev, "no device onboard\n");
err = -ENODEV;
goto out_remap;
}
platform_set_drvdata(pdev, rtc_data);
mxs_reset_block(rtc_data->io);
writel(STMP3XXX_RTC_PERSISTENT0_ALARM_EN |
STMP3XXX_RTC_PERSISTENT0_ALARM_WAKE_EN |
STMP3XXX_RTC_PERSISTENT0_ALARM_WAKE,
rtc_data->io + STMP3XXX_RTC_PERSISTENT0_CLR);
writel(STMP3XXX_RTC_CTRL_ONEMSEC_IRQ_EN |
STMP3XXX_RTC_CTRL_ALARM_IRQ_EN,
rtc_data->io + STMP3XXX_RTC_CTRL_CLR);
rtc_data->rtc = rtc_device_register(pdev->name, &pdev->dev,
&stmp3xxx_rtc_ops, THIS_MODULE);
if (IS_ERR(rtc_data->rtc)) {
err = PTR_ERR(rtc_data->rtc);
goto out_remap;
}
err = request_irq(rtc_data->irq_alarm, stmp3xxx_rtc_interrupt, 0,
"RTC alarm", &pdev->dev);
if (err) {
dev_err(&pdev->dev, "Cannot claim IRQ%d\n",
rtc_data->irq_alarm);
goto out_irq_alarm;
}
return 0;
out_irq_alarm:
rtc_device_unregister(rtc_data->rtc);
out_remap:
platform_set_drvdata(pdev, NULL);
iounmap(rtc_data->io);
out_free:
kfree(rtc_data);
return err;
}
/*
* Nominally, the purpose of this function is to look for or create the bad
* block table. In fact, since the we call this function at the very end of
* the initialization process started by nand_scan(), and we doesn't have a
* more formal mechanism, we "hook" this function to continue init process.
*
* At this point, the physical NAND Flash chips have been identified and
* counted, so we know the physical geometry. This enables us to make some
* important configuration decisions.
*
* The return value of this function propagates directly back to this driver's
* call to nand_scan(). Anything other than zero will cause this driver to
* tear everything down and declare failure.
*/
static int mxs_nand_scan_bbt(struct mtd_info *mtd)
{
struct nand_chip *nand = mtd_to_nand(mtd);
struct mxs_nand_info *nand_info = nand_get_controller_data(nand);
struct mxs_bch_regs *bch_regs = (struct mxs_bch_regs *)MXS_BCH_BASE;
uint32_t tmp;
if (mtd->oobsize > MXS_NAND_CHUNK_DATA_CHUNK_SIZE) {
galois_field = 14;
chunk_data_size = MXS_NAND_CHUNK_DATA_CHUNK_SIZE * 2;
}
if (mtd->oobsize > chunk_data_size) {
printf("Not support the NAND chips whose oob size is larger then %d bytes!\n", chunk_data_size);
return -EINVAL;
}
/* Configure BCH and set NFC geometry */
mxs_reset_block(&bch_regs->hw_bch_ctrl_reg);
/* Configure layout 0 */
tmp = (mxs_nand_ecc_chunk_cnt(mtd->writesize) - 1)
<< BCH_FLASHLAYOUT0_NBLOCKS_OFFSET;
tmp |= MXS_NAND_METADATA_SIZE << BCH_FLASHLAYOUT0_META_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT0_ECC0_OFFSET;
tmp |= chunk_data_size >> MXS_NAND_CHUNK_DATA_CHUNK_SIZE_SHIFT;
tmp |= (14 == galois_field ? 1 : 0) <<
BCH_FLASHLAYOUT0_GF13_0_GF14_1_OFFSET;
writel(tmp, &bch_regs->hw_bch_flash0layout0);
tmp = (mtd->writesize + mtd->oobsize)
<< BCH_FLASHLAYOUT1_PAGE_SIZE_OFFSET;
tmp |= (mxs_nand_get_ecc_strength(mtd->writesize, mtd->oobsize) >> 1)
<< BCH_FLASHLAYOUT1_ECCN_OFFSET;
tmp |= chunk_data_size >> MXS_NAND_CHUNK_DATA_CHUNK_SIZE_SHIFT;
tmp |= (14 == galois_field ? 1 : 0) <<
BCH_FLASHLAYOUT1_GF13_0_GF14_1_OFFSET;
writel(tmp, &bch_regs->hw_bch_flash0layout1);
/* Set *all* chip selects to use layout 0 */
writel(0, &bch_regs->hw_bch_layoutselect);
/* Enable BCH complete interrupt */
writel(BCH_CTRL_COMPLETE_IRQ_EN, &bch_regs->hw_bch_ctrl_set);
/* Hook some operations at the MTD level. */
if (mtd->_read_oob != mxs_nand_hook_read_oob) {
nand_info->hooked_read_oob = mtd->_read_oob;
mtd->_read_oob = mxs_nand_hook_read_oob;
}
if (mtd->_write_oob != mxs_nand_hook_write_oob) {
nand_info->hooked_write_oob = mtd->_write_oob;
mtd->_write_oob = mxs_nand_hook_write_oob;
}
if (mtd->_block_markbad != mxs_nand_hook_block_markbad) {
nand_info->hooked_block_markbad = mtd->_block_markbad;
mtd->_block_markbad = mxs_nand_hook_block_markbad;
}
/* We use the reference implementation for bad block management. */
return nand_default_bbt(mtd);
}
