#pypp 0 // Iris: micro-kernel for a capability-based operating system. // nanonote/jz4740.ccp: Chip features. Most of this file is // copied from the Linux source files include/asm-mips/jz4740/{ops,regs}.h, // which don't have a copyright statement or license in the header. // Copyright 2009 Bas Wijnen // // 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 . #ifndef __JZ4740_HH__ #define __JZ4740_HH__ // Main clock, for cpu, serial port, and with divisors for most other hardware #define JZ_EXTAL 12000000 /* 12 MHz */ // RTC clock #define RTC_CLOCK 32768 /* 32.768 KHz */ // Interrupt source used for system timer #define TIMER_INTERRUPT IRQ_TCU0 // Physical addresses are where they really are. #define CPM_PHYSICAL 0x10000000 #define INTC_PHYSICAL 0x10001000 #define TCU_PHYSICAL 0x10002000 #define WDT_PHYSICAL 0x10002000 #define RTC_PHYSICAL 0x10003000 #define GPIO_PHYSICAL 0x10010000 #define AIC_PHYSICAL 0x10020000 #define MSC_PHYSICAL 0x10021000 #define UART0_PHYSICAL 0x10030000 #define I2C_PHYSICAL 0x10042000 #define SSI_PHYSICAL 0x10043000 #define SADC_PHYSICAL 0x10070000 #define EMC_PHYSICAL 0x13010000 #define DMAC_PHYSICAL 0x13020000 #define UHC_PHYSICAL 0x13030000 #define UDC_PHYSICAL 0x13040000 #define LCD_PHYSICAL 0x13050000 #define SLCD_PHYSICAL 0x13050000 #define CIM_PHYSICAL 0x13060000 #define ETH_PHYSICAL 0x13100000 #ifdef __KERNEL__ // In kernel space you need to add 0xa0000000 to see them unmapped uncached in kseg2. #define CPM_BASE (0xa0000000 + CPM_PHYSICAL) #define INTC_BASE (0xa0000000 + INTC_PHYSICAL) #define TCU_BASE (0xa0000000 + TCU_PHYSICAL) #define WDT_BASE (0xa0000000 + WDT_PHYSICAL) #define RTC_BASE (0xa0000000 + RTC_PHYSICAL) #define GPIO_BASE (0xa0000000 + GPIO_PHYSICAL) #define AIC_BASE (0xa0000000 + AIC_PHYSICAL) #define MSC_BASE (0xa0000000 + MSC_PHYSICAL) #define UART0_BASE (0xa0000000 + UART0_PHYSICAL) #define I2C_BASE (0xa0000000 + I2C_PHYSICAL) #define SSI_BASE (0xa0000000 + SSI_PHYSICAL) #define SADC_BASE (0xa0000000 + SADC_PHYSICAL) #define EMC_BASE (0xa0000000 + EMC_PHYSICAL) #define DMAC_BASE (0xa0000000 + DMAC_PHYSICAL) #define UHC_BASE (0xa0000000 + UHC_PHYSICAL) #define UDC_BASE (0xa0000000 + UDC_PHYSICAL) #define LCD_BASE (0xa0000000 + LCD_PHYSICAL) #define SLCD_BASE (0xa0000000 + SLCD_PHYSICAL) #define CIM_BASE (0xa0000000 + CIM_PHYSICAL) #define ETH_BASE (0xa0000000 + ETH_PHYSICAL) // udelay should not be called from the kernel. #define udelay(x) dpanic (x, "udelay called") #else // In user space, they just need a mapping. #define UNMAPPED_BASE 0x00000000 #define CPM_BASE 0x00001000 #define INTC_BASE 0x00002000 #define TCU_BASE 0x00003000 #define WDT_BASE 0x00004000 #define RTC_BASE 0x00005000 #define GPIO_BASE 0x00006000 #define AIC_BASE 0x00007000 #define MSC_BASE 0x00008000 #define UART0_BASE 0x00009000 #define I2C_BASE 0x0000a000 #define SSI_BASE 0x0000b000 #define SADC_BASE 0x0000c000 #define EMC_BASE 0x0000d000 #define DMAC_BASE 0x0000e000 #define UHC_BASE 0x0000f000 #define UDC_BASE 0x00010000 #define LCD_BASE 0x00011000 #define SLCD_BASE 0x00012000 #define CIM_BASE 0x00013000 #define ETH_BASE 0x00014000 // Default lcd framebuffer mapping space. #define LCD_FRAMEBUFFER_BASE ((unsigned *)0x00015000) // Map IO memory (requires a priviledged Iris::my_thread capability). #include static void __map_io (unsigned physical, unsigned mapping): Iris::Page p = Iris::my_memory.create_page () // false means not cachable; false means don't free when done. p.alloc_physical (physical, false, false) Iris::my_memory.map (p, mapping) Iris::free_cap (p) #define map_cpm() do { __map_io (CPM_PHYSICAL, CPM_BASE); } while (0) #define map_intc() do { __map_io (INTC_PHYSICAL, INTC_BASE); } while (0) #define map_tcu() do { __map_io (TCU_PHYSICAL, TCU_BASE); } while (0) #define map_wdt() do { __map_io (WDT_PHYSICAL, WDT_BASE); } while (0) #define map_rtc() do { __map_io (RTC_PHYSICAL, RTC_BASE); } while (0) #define map_gpio() do { __map_io (GPIO_PHYSICAL, GPIO_BASE); } while (0) #define map_aic() do { __map_io (AIC_PHYSICAL, AIC_BASE); } while (0) #define map_msc() do { __map_io (MSC_PHYSICAL, MSC_BASE); } while (0) #define map_uart0() do { __map_io (UART0_PHYSICAL, UART0_BASE); } while (0) #define map_i2c() do { __map_io (I2C_PHYSICAL, I2C_BASE); } while (0) #define map_ssi() do { __map_io (SSI_PHYSICAL, SSI_BASE); } while (0) #define map_sadc() do { __map_io (SADC_PHYSICAL, SADC_BASE); } while (0) #define map_emc() do { __map_io (EMC_PHYSICAL, EMC_BASE); } while (0) #define map_dmac() do { __map_io (DMAC_PHYSICAL, DMAC_BASE); } while (0) #define map_uhc() do { __map_io (UHC_PHYSICAL, UHC_BASE); } while (0) #define map_udc() do { __map_io (UDC_PHYSICAL, UDC_BASE); } while (0) #define map_lcd() do { __map_io (LCD_PHYSICAL, LCD_BASE); } while (0) #define map_slcd() do { __map_io (SLCD_PHYSICAL, SLCD_BASE); } while (0) #define map_cim() do { __map_io (CIM_PHYSICAL, CIM_BASE); } while (0) #define map_eth() do { __map_io (ETH_PHYSICAL, ETH_BASE); } while (0) // udelay implementation void cdelay (unsigned cs): Iris::my_receiver.set_alarm (cs + 1) Iris::Cap ().call () #endif #define REG8(x) (*(volatile unsigned char *)(x)) #define REG16(x) (*(volatile unsigned short *)(x)) #define REG32(x) (*(volatile unsigned *)(x)) //************************************************************************ // INTC (Interrupt Controller) //************************************************************************ #define INTC_ISR REG32 (INTC_BASE + 0x00) #define INTC_IMR REG32 (INTC_BASE + 0x04) #define INTC_IMSR REG32 (INTC_BASE + 0x08) #define INTC_IMCR REG32 (INTC_BASE + 0x0c) #define INTC_IPR REG32 (INTC_BASE + 0x10) #define IRQ_I2C 1 #define IRQ_UHC 3 #define IRQ_UART0 9 #define IRQ_SADC 12 #define IRQ_MSC 14 #define IRQ_RTC 15 #define IRQ_SSI 16 #define IRQ_CIM 17 #define IRQ_AIC 18 #define IRQ_DMAC 20 #define IRQ_TCU2 21 #define IRQ_TCU1 22 #define IRQ_TCU0 23 #define IRQ_UDC 24 #define IRQ_GPIO3 25 #define IRQ_GPIO2 26 #define IRQ_GPIO1 27 #define IRQ_GPIO0 28 #define IRQ_IPU 29 #define IRQ_LCD 30 //************************************************************************ // RTC //************************************************************************ #define RTC_RCR REG32 (RTC_BASE + 0x00) // RTC Control Register #define RTC_RSR REG32 (RTC_BASE + 0x04) // RTC Second Register #define RTC_RSAR REG32 (RTC_BASE + 0x08) // RTC Second Alarm Register #define RTC_RGR REG32 (RTC_BASE + 0x0c) // RTC Regulator Register #define RTC_HCR REG32 (RTC_BASE + 0x20) // Hibernate Control Register #define RTC_HWFCR REG32 (RTC_BASE + 0x24) // Hibernate Wakeup Filter Counter Reg #define RTC_HRCR REG32 (RTC_BASE + 0x28) // Hibernate Reset Counter Register #define RTC_HWCR REG32 (RTC_BASE + 0x2c) // Hibernate Wakeup Control Register #define RTC_HWRSR REG32 (RTC_BASE + 0x30) // Hibernate Wakeup Status Register #define RTC_HSPR REG32 (RTC_BASE + 0x34) // Hibernate Scratch Pattern Register // RTC Control Register #define RTC_RCR_WRDY_BIT 7 #define RTC_RCR_WRDY (1 << 7) // Write Ready Flag #define RTC_RCR_1HZ_BIT 6 #define RTC_RCR_1HZ (1 << RTC_RCR_1HZ_BIT) // 1Hz Flag #define RTC_RCR_1HZIE (1 << 5) // 1Hz Interrupt Enable #define RTC_RCR_AF_BIT 4 #define RTC_RCR_AF (1 << RTC_RCR_AF_BIT) // Alarm Flag #define RTC_RCR_AIE (1 << 3) // Alarm Interrupt Enable #define RTC_RCR_AE (1 << 2) // Alarm Enable #define RTC_RCR_RTCE (1 << 0) // RTC Enable // RTC Regulator Register #define RTC_RGR_LOCK (1 << 31) // Lock Bit #define RTC_RGR_ADJC_BIT 16 #define RTC_RGR_ADJC_MASK (0x3ff << RTC_RGR_ADJC_BIT) #define RTC_RGR_NC1HZ_BIT 0 #define RTC_RGR_NC1HZ_MASK (0xffff << RTC_RGR_NC1HZ_BIT) // Hibernate Control Register #define RTC_HCR_PD (1 << 0) // Power Down // Hibernate Wakeup Filter Counter Register #define RTC_HWFCR_BIT 5 #define RTC_HWFCR_MASK (0x7ff << RTC_HWFCR_BIT) // Hibernate Reset Counter Register #define RTC_HRCR_BIT 5 #define RTC_HRCR_MASK (0x7f << RTC_HRCR_BIT) // Hibernate Wakeup Control Register #define RTC_HWCR_EALM (1 << 0) // RTC alarm wakeup enable // Hibernate Wakeup Status Register #define RTC_HWRSR_HR (1 << 5) // Hibernate reset #define RTC_HWRSR_PPR (1 << 4) // PPR reset #define RTC_HWRSR_PIN (1 << 1) // Wakeup pin status bit #define RTC_HWRSR_ALM (1 << 0) // RTC alarm status bit //************************************************************************ // CPM (Clock reset and Power control Management) //************************************************************************ #define CPM_CPCCR REG32 (CPM_BASE+0x00) #define CPM_CPPCR REG32 (CPM_BASE+0x10) #define CPM_I2SCDR REG32 (CPM_BASE+0x60) #define CPM_LPCDR REG32 (CPM_BASE+0x64) #define CPM_MSCCDR REG32 (CPM_BASE+0x68) #define CPM_UHCCDR REG32 (CPM_BASE+0x6C) #define CPM_SSICDR REG32 (CPM_BASE+0x74) #define CPM_LCR REG32 (CPM_BASE+0x04) #define CPM_CLKGR REG32 (CPM_BASE+0x20) #define CPM_SCR REG32 (CPM_BASE+0x24) #define CPM_HCR REG32 (CPM_BASE+0x30) #define CPM_HWFCR REG32 (CPM_BASE+0x34) #define CPM_HRCR REG32 (CPM_BASE+0x38) #define CPM_HWCR REG32 (CPM_BASE+0x3c) #define CPM_HWSR REG32 (CPM_BASE+0x40) #define CPM_HSPR REG32 (CPM_BASE+0x44) #define CPM_RSR REG32 (CPM_BASE+0x08) // Clock Control Register #define CPM_CPCCR_I2CS (1 << 31) #define CPM_CPCCR_CLKOEN (1 << 30) #define CPM_CPCCR_UCS (1 << 29) #define CPM_CPCCR_UDIV_BIT 23 #define CPM_CPCCR_UDIV_MASK (0x3f << CPM_CPCCR_UDIV_BIT) #define CPM_CPCCR_CE (1 << 22) #define CPM_CPCCR_PCS (1 << 21) #define CPM_CPCCR_LDIV_BIT 16 #define CPM_CPCCR_LDIV_MASK (0x1f << CPM_CPCCR_LDIV_BIT) #define CPM_CPCCR_MDIV_BIT 12 #define CPM_CPCCR_MDIV_MASK (0x0f << CPM_CPCCR_MDIV_BIT) #define CPM_CPCCR_PDIV_BIT 8 #define CPM_CPCCR_PDIV_MASK (0x0f << CPM_CPCCR_PDIV_BIT) #define CPM_CPCCR_HDIV_BIT 4 #define CPM_CPCCR_HDIV_MASK (0x0f << CPM_CPCCR_HDIV_BIT) #define CPM_CPCCR_CDIV_BIT 0 #define CPM_CPCCR_CDIV_MASK (0x0f << CPM_CPCCR_CDIV_BIT) // I2S Clock Divider Register #define CPM_I2SCDR_I2SDIV_BIT 0 #define CPM_I2SCDR_I2SDIV_MASK (0x1ff << CPM_I2SCDR_I2SDIV_BIT) // LCD Pixel Clock Divider Register #define CPM_LPCDR_PIXDIV_BIT 0 #define CPM_LPCDR_PIXDIV_MASK (0x1ff << CPM_LPCDR_PIXDIV_BIT) // MSC Clock Divider Register #define CPM_MSCCDR_MSCDIV_BIT 0 #define CPM_MSCCDR_MSCDIV_MASK (0x1f << CPM_MSCCDR_MSCDIV_BIT) // UHC Clock Divider Register #define CPM_UHCCDR_UHCDIV_BIT 0 #define CPM_UHCCDR_UHCDIV_MASK (0xf << CPM_UHCCDR_UHCDIV_BIT) // SSI Clock Divider Register #define CPM_SSICDR_SCS (1<<31) // SSI clock source selection, 0:EXCLK, 1: PLL #define CPM_SSICDR_SSIDIV_BIT 0 #define CPM_SSICDR_SSIDIV_MASK (0xf << CPM_SSICDR_SSIDIV_BIT) // PLL Control Register #define CPM_CPPCR_PLLM_BIT 23 #define CPM_CPPCR_PLLM_MASK (0x1ff << CPM_CPPCR_PLLM_BIT) #define CPM_CPPCR_PLLN_BIT 18 #define CPM_CPPCR_PLLN_MASK (0x1f << CPM_CPPCR_PLLN_BIT) #define CPM_CPPCR_PLLOD_BIT 16 #define CPM_CPPCR_PLLOD_MASK (0x03 << CPM_CPPCR_PLLOD_BIT) #define CPM_CPPCR_PLLS (1 << 10) #define CPM_CPPCR_PLLBP (1 << 9) #define CPM_CPPCR_PLLEN (1 << 8) #define CPM_CPPCR_PLLST_BIT 0 #define CPM_CPPCR_PLLST_MASK (0xff << CPM_CPPCR_PLLST_BIT) // Low Power Control Register #define CPM_LCR_DOZE_DUTY_BIT 3 #define CPM_LCR_DOZE_DUTY_MASK (0x1f << CPM_LCR_DOZE_DUTY_BIT) #define CPM_LCR_DOZE_ON (1 << 2) #define CPM_LCR_LPM_BIT 0 #define CPM_LCR_LPM_MASK (0x3 << CPM_LCR_LPM_BIT) #define CPM_LCR_LPM_IDLE (0x0 << CPM_LCR_LPM_BIT) #define CPM_LCR_LPM_SLEEP (0x1 << CPM_LCR_LPM_BIT) // Clock Gate Register #define CPM_CLKGR_UART1 (1 << 15) #define CPM_CLKGR_UHC (1 << 14) #define CPM_CLKGR_IPU (1 << 13) #define CPM_CLKGR_DMAC (1 << 12) #define CPM_CLKGR_UDC (1 << 11) #define CPM_CLKGR_LCD (1 << 10) #define CPM_CLKGR_CIM (1 << 9) #define CPM_CLKGR_SADC (1 << 8) #define CPM_CLKGR_MSC (1 << 7) #define CPM_CLKGR_AIC1 (1 << 6) #define CPM_CLKGR_AIC2 (1 << 5) #define CPM_CLKGR_SSI (1 << 4) #define CPM_CLKGR_I2C (1 << 3) #define CPM_CLKGR_RTC (1 << 2) #define CPM_CLKGR_TCU (1 << 1) #define CPM_CLKGR_UART0 (1 << 0) // Sleep Control Register #define CPM_SCR_O1ST_BIT 8 #define CPM_SCR_O1ST_MASK (0xff << CPM_SCR_O1ST_BIT) #define CPM_SCR_USBPHY_ENABLE (1 << 6) #define CPM_SCR_OSC_ENABLE (1 << 4) // Hibernate Control Register #define CPM_HCR_PD (1 << 0) // Wakeup Filter Counter Register in Hibernate Mode #define CPM_HWFCR_TIME_BIT 0 #define CPM_HWFCR_TIME_MASK (0x3ff << CPM_HWFCR_TIME_BIT) // Reset Counter Register in Hibernate Mode #define CPM_HRCR_TIME_BIT 0 #define CPM_HRCR_TIME_MASK (0x7f << CPM_HRCR_TIME_BIT) // Wakeup Control Register in Hibernate Mode #define CPM_HWCR_WLE_LOW (0 << 2) #define CPM_HWCR_WLE_HIGH (1 << 2) #define CPM_HWCR_PIN_WAKEUP (1 << 1) #define CPM_HWCR_RTC_WAKEUP (1 << 0) // Wakeup Status Register in Hibernate Mode #define CPM_HWSR_WSR_PIN (1 << 1) #define CPM_HWSR_WSR_RTC (1 << 0) // Reset Status Register #define CPM_RSR_HR (1 << 2) #define CPM_RSR_WR (1 << 1) #define CPM_RSR_PR (1 << 0) //************************************************************************ // TCU (Timer Counter Unit) //************************************************************************ #define TCU_TSR REG32 (TCU_BASE + 0x1C) // Timer Stop Register #define TCU_TSSR REG32 (TCU_BASE + 0x2C) // Timer Stop Set Register #define TCU_TSCR REG32 (TCU_BASE + 0x3C) // Timer Stop Clear Register #define TCU_TER REG8 (TCU_BASE + 0x10) // Timer Counter Enable Register #define TCU_TESR REG8 (TCU_BASE + 0x14) // Timer Counter Enable Set Register #define TCU_TECR REG8 (TCU_BASE + 0x18) // Timer Counter Enable Clear Register #define TCU_TFR REG32 (TCU_BASE + 0x20) // Timer Flag Register #define TCU_TFSR REG32 (TCU_BASE + 0x24) // Timer Flag Set Register #define TCU_TFCR REG32 (TCU_BASE + 0x28) // Timer Flag Clear Register #define TCU_TMR REG32 (TCU_BASE + 0x30) // Timer Mask Register #define TCU_TMSR REG32 (TCU_BASE + 0x34) // Timer Mask Set Register #define TCU_TMCR REG32 (TCU_BASE + 0x38) // Timer Mask Clear Register // n = 0,1,2,3,4,5 #define TCU_TDFR(n) REG16 (TCU_BASE + (0x40 + (n)*0x10)) // Timer Data Full Reg #define TCU_TDHR(n) REG16 (TCU_BASE + (0x44 + (n)*0x10)) // Timer Data Half Reg #define TCU_TCNT(n) REG16 (TCU_BASE + (0x48 + (n)*0x10)) // Timer Counter Reg #define TCU_TCSR(n) REG16 (TCU_BASE + (0x4C + (n)*0x10)) // Timer Control Reg // Register definitions #define TCU_TCSR_PWM_SD (1 << 9) #define TCU_TCSR_PWM_INITL_HIGH (1 << 8) #define TCU_TCSR_PWM_EN (1 << 7) #define TCU_TCSR_PRESCALE_BIT 3 #define TCU_TCSR_PRESCALE_MASK (0x7 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE1 (0x0 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE4 (0x1 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE16 (0x2 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE64 (0x3 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE256 (0x4 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_PRESCALE1024 (0x5 << TCU_TCSR_PRESCALE_BIT) #define TCU_TCSR_EXT_EN (1 << 2) #define TCU_TCSR_RTC_EN (1 << 1) #define TCU_TCSR_PCK_EN (1 << 0) #define TCU_TER_TCEN(n) (1 << (n)) #define TCU_TESR_TCST(n) (1 << (n)) #define TCU_TECR_TCCL(n) (1 << (n)) #define TCU_TFR_HFLAG(n) (1 << ((n) + 16)) #define TCU_TFR_FFLAG(n) (1 << (n)) #define TCU_TFSR_HFLAG(n) (1 << ((n) + 16)) #define TCU_TFSR_FFLAG(n) (1 << (n)) #define TCU_TFCR_HFLAG(n) (1 << ((n) + 16)) #define TCU_TFCR_FFLAG(n) (1 << (n)) #define TCU_TMR_HMASK(n) (1 << ((n) + 16)) #define TCU_TMR_FMASK(n) (1 << (n)) #define TCU_TMSR_HMST(n) (1 << ((n) + 16)) #define TCU_TMSR_FMST(n) (1 << (n)) #define TCU_TMCR_HMCL(n) (1 << ((n) + 16)) #define TCU_TMCR_FMCL(n) (1 << (n)) #define TCU_TSR_WDTS (1 << 16) #define TCU_TSR_STOP(n) (1 << (n)) #define TCU_TSSR_WDTSS (1 << 16) #define TCU_TSSR_STPS(n) (1 << (n)) #define TCU_TSSR_WDTSC (1 << 16) #define TCU_TSSR_STPC(n) (1 << (n)) //************************************************************************ // WDT (WatchDog Timer) //************************************************************************ #define WDT_TDR REG16 (WDT_BASE + 0x00) #define WDT_TCER REG8 (WDT_BASE + 0x04) #define WDT_TCNT REG16 (WDT_BASE + 0x08) #define WDT_TCSR REG16 (WDT_BASE + 0x0C) // Register definition #define WDT_TCSR_PRESCALE_BIT 3 #define WDT_TCSR_PRESCALE_MASK (0x7 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE1 (0x0 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE4 (0x1 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE16 (0x2 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE64 (0x3 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE256 (0x4 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_PRESCALE1024 (0x5 << WDT_TCSR_PRESCALE_BIT) #define WDT_TCSR_EXT_EN (1 << 2) #define WDT_TCSR_RTC_EN (1 << 1) #define WDT_TCSR_PCK_EN (1 << 0) #define WDT_TCER_TCEN (1 << 0) //************************************************************************ // DMAC (DMA Controller) //************************************************************************ #define MAX_DMA_NUM 6 // max 6 channels #define DMAC_DSAR(n) REG32 (DMAC_BASE + (0x00 + (n) * 0x20)) // DMA source address #define DMAC_DTAR(n) REG32 (DMAC_BASE + (0x04 + (n) * 0x20)) // DMA target address #define DMAC_DTCR(n) REG32 (DMAC_BASE + (0x08 + (n) * 0x20)) // DMA transfer count #define DMAC_DRSR(n) REG32 (DMAC_BASE + (0x0c + (n) * 0x20)) // DMA request source #define DMAC_DCCSR(n) REG32 (DMAC_BASE + (0x10 + (n) * 0x20)) // DMA control/status #define DMAC_DCMD(n) REG32 (DMAC_BASE + (0x14 + (n) * 0x20)) // DMA command #define DMAC_DDA(n) REG32 (DMAC_BASE + (0x18 + (n) * 0x20)) // DMA descriptor address #define DMAC_DMACR REG32 (DMAC_BASE + 0x0300) // DMA control register #define DMAC_DMAIPR REG32 (DMAC_BASE + 0x0304) // DMA interrupt pending #define DMAC_DMADBR REG32 (DMAC_BASE + 0x0308) // DMA doorbell #define DMAC_DMADBSR REG32 (DMAC_BASE + 0x030C) // DMA doorbell set // DMA request source register #define DMAC_DRSR_RS_BIT 0 #define DMAC_DRSR_RS_MASK (0x1f << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_AUTO (8 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_UART0OUT (20 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_UART0IN (21 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_SSIOUT (22 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_SSIIN (23 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_AICOUT (24 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_AICIN (25 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_MSCOUT (26 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_MSCIN (27 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_TCU (28 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_SADC (29 << DMAC_DRSR_RS_BIT) #define DMAC_DRSR_RS_SLCD (30 << DMAC_DRSR_RS_BIT) // DMA channel control/status register #define DMAC_DCCSR_NDES (1 << 31) // descriptor (0) or not (1) ? #define DMAC_DCCSR_CDOA_BIT 16 // copy of DMA offset address #define DMAC_DCCSR_CDOA_MASK (0xff << DMAC_DCCSR_CDOA_BIT) #define DMAC_DCCSR_INV (1 << 6) // descriptor invalid #define DMAC_DCCSR_AR (1 << 4) // address error #define DMAC_DCCSR_TT (1 << 3) // transfer terminated #define DMAC_DCCSR_HLT (1 << 2) // DMA halted #define DMAC_DCCSR_CT (1 << 1) // count terminated #define DMAC_DCCSR_EN (1 << 0) // channel enable bit // DMA channel command register #define DMAC_DCMD_SAI (1 << 23) // source address increment #define DMAC_DCMD_DAI (1 << 22) // dest address increment #define DMAC_DCMD_RDIL_BIT 16 // request detection interval length #define DMAC_DCMD_RDIL_MASK (0x0f << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_IGN (0 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_2 (1 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_4 (2 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_8 (3 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_12 (4 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_16 (5 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_20 (6 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_24 (7 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_28 (8 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_32 (9 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_48 (10 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_60 (11 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_64 (12 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_124 (13 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_128 (14 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_RDIL_200 (15 << DMAC_DCMD_RDIL_BIT) #define DMAC_DCMD_SWDH_BIT 14 // source port width #define DMAC_DCMD_SWDH_MASK (0x03 << DMAC_DCMD_SWDH_BIT) #define DMAC_DCMD_SWDH_32 (0 << DMAC_DCMD_SWDH_BIT) #define DMAC_DCMD_SWDH_8 (1 << DMAC_DCMD_SWDH_BIT) #define DMAC_DCMD_SWDH_16 (2 << DMAC_DCMD_SWDH_BIT) #define DMAC_DCMD_DWDH_BIT 12 // dest port width #define DMAC_DCMD_DWDH_MASK (0x03 << DMAC_DCMD_DWDH_BIT) #define DMAC_DCMD_DWDH_32 (0 << DMAC_DCMD_DWDH_BIT) #define DMAC_DCMD_DWDH_8 (1 << DMAC_DCMD_DWDH_BIT) #define DMAC_DCMD_DWDH_16 (2 << DMAC_DCMD_DWDH_BIT) #define DMAC_DCMD_DS_BIT 8 // transfer data size of a data unit #define DMAC_DCMD_DS_MASK (0x07 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_DS_32BIT (0 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_DS_8BIT (1 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_DS_16BIT (2 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_DS_16BYTE (3 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_DS_32BYTE (4 << DMAC_DCMD_DS_BIT) #define DMAC_DCMD_TM (1 << 7) // transfer mode: 0-single 1-block #define DMAC_DCMD_DES_V (1 << 4) // descriptor valid flag #define DMAC_DCMD_DES_VM (1 << 3) // descriptor valid mask: 1:support V-bit #define DMAC_DCMD_DES_VIE (1 << 2) // DMA valid error interrupt enable #define DMAC_DCMD_TIE (1 << 1) // DMA transfer interrupt enable #define DMAC_DCMD_LINK (1 << 0) // descriptor link enable // DMA descriptor address register #define DMAC_DDA_BASE_BIT 12 // descriptor base address #define DMAC_DDA_BASE_MASK (0x0fffff << DMAC_DDA_BASE_BIT) #define DMAC_DDA_OFFSET_BIT 4 // descriptor offset address #define DMAC_DDA_OFFSET_MASK (0x0ff << DMAC_DDA_OFFSET_BIT) // DMA control register #define DMAC_DMACR_PR_BIT 8 // channel priority mode #define DMAC_DMACR_PR_MASK (0x03 << DMAC_DMACR_PR_BIT) #define DMAC_DMACR_PR_012345 (0 << DMAC_DMACR_PR_BIT) #define DMAC_DMACR_PR_023145 (1 << DMAC_DMACR_PR_BIT) #define DMAC_DMACR_PR_201345 (2 << DMAC_DMACR_PR_BIT) #define DMAC_DMACR_PR_RR (3 << DMAC_DMACR_PR_BIT) // round robin #define DMAC_DMACR_HLT (1 << 3) // DMA halt flag #define DMAC_DMACR_AR (1 << 2) // address error flag #define DMAC_DMACR_DMAE (1 << 0) // DMA enable bit #define DMAC_DMADBR_DB (1 << 5) // doorbell #define DMAC_DMADBSR_DBS (1 << 5) // enable doorbell #define DMAC_DMAIPR_CIRQ(n) (1 << n) // irq pending status for channel n //************************************************************************ // GPIO (General-Purpose I/O Ports) //************************************************************************ #define MAX_GPIO_NUM 128 //n = 0,1,2,3 #define GPIO_PXPIN(n) REG32 (GPIO_BASE + (0x00 + (n)*0x100)) // PIN Level Register #define GPIO_PXDAT(n) REG32 (GPIO_BASE + (0x10 + (n)*0x100)) // Port Data Register 1: interrupt pending #define GPIO_PXDATS(n) REG32 (GPIO_BASE + (0x14 + (n)*0x100)) // Port Data Set Register #define GPIO_PXDATC(n) REG32 (GPIO_BASE + (0x18 + (n)*0x100)) // Port Data Clear Register #define GPIO_PXIM(n) REG32 (GPIO_BASE + (0x20 + (n)*0x100)) // Interrupt Mask Register 1: mask pin interrupt #define GPIO_PXIMS(n) REG32 (GPIO_BASE + (0x24 + (n)*0x100)) // Interrupt Mask Set Reg #define GPIO_PXIMC(n) REG32 (GPIO_BASE + (0x28 + (n)*0x100)) // Interrupt Mask Clear Reg #define GPIO_PXPE(n) REG32 (GPIO_BASE + (0x30 + (n)*0x100)) // Pull Enable Register 1: disable pull up/down #define GPIO_PXPES(n) REG32 (GPIO_BASE + (0x34 + (n)*0x100)) // Pull Enable Set Reg. #define GPIO_PXPEC(n) REG32 (GPIO_BASE + (0x38 + (n)*0x100)) // Pull Enable Clear Reg. #define GPIO_PXFUN(n) REG32 (GPIO_BASE + (0x40 + (n)*0x100)) // Function Register 0: gpio; 1: function #define GPIO_PXFUNS(n) REG32 (GPIO_BASE + (0x44 + (n)*0x100)) // Function Set Register #define GPIO_PXFUNC(n) REG32 (GPIO_BASE + (0x48 + (n)*0x100)) // Function Clear Register #define GPIO_PXSEL(n) REG32 (GPIO_BASE + (0x50 + (n)*0x100)) // Select Register 0: gpio/fun0; 1: intr/fun1 #define GPIO_PXSELS(n) REG32 (GPIO_BASE + (0x54 + (n)*0x100)) // Select Set Register #define GPIO_PXSELC(n) REG32 (GPIO_BASE + (0x58 + (n)*0x100)) // Select Clear Register #define GPIO_PXDIR(n) REG32 (GPIO_BASE + (0x60 + (n)*0x100)) // Direction Register 0:input/low-level-trig/falling-edge-trig, 1:output/high-level-trig/rising-edge-trig #define GPIO_PXDIRS(n) REG32 (GPIO_BASE + (0x64 + (n)*0x100)) // Direction Set Register #define GPIO_PXDIRC(n) REG32 (GPIO_BASE + (0x68 + (n)*0x100)) // Direction Clear Register #define GPIO_PXTRG(n) REG32 (GPIO_BASE + (0x70 + (n)*0x100)) // Trigger Register 0:level-trigger, 1:edge-trigger #define GPIO_PXTRGS(n) REG32 (GPIO_BASE + (0x74 + (n)*0x100)) // Trigger Set Register #define GPIO_PXTRGC(n) REG32 (GPIO_BASE + (0x78 + (n)*0x100)) // Trigger Set Register #define GPIO_PXFLG(n) REG32 (GPIO_BASE + (0x80 + (n)*0x100)) // Port Flag Register interrupt flag #define GPIO_PXFLGC(n) REG32 (GPIO_BASE + (0x14 + (n)*0x100)) // Port Flag Clear Register //************************************************************************ // UART //************************************************************************ #define IRDA_BASE UART0_BASE #define UART_BASE UART0_BASE #define UART_OFF 0x1000 // Register Offset #define OFF_RDR (0x00) // R 8b H'xx #define OFF_TDR (0x00) // W 8b H'xx #define OFF_DLLR (0x00) // RW 8b H'00 #define OFF_DLHR (0x04) // RW 8b H'00 #define OFF_IER (0x04) // RW 8b H'00 #define OFF_ISR (0x08) // R 8b H'01 #define OFF_FCR (0x08) // W 8b H'00 #define OFF_LCR (0x0C) // RW 8b H'00 #define OFF_MCR (0x10) // RW 8b H'00 #define OFF_LSR (0x14) // R 8b H'00 #define OFF_MSR (0x18) // R 8b H'00 #define OFF_SPR (0x1C) // RW 8b H'00 #define OFF_SIRCR (0x20) // RW 8b H'00, UART0 #define OFF_UMR (0x24) // RW 8b H'00, UART M Register #define OFF_UACR (0x28) // RW 8b H'00, UART Add Cycle Register // Register Address #define UART0_RDR REG8 (UART0_BASE + OFF_RDR) #define UART0_TDR REG8 (UART0_BASE + OFF_TDR) #define UART0_DLLR REG8 (UART0_BASE + OFF_DLLR) #define UART0_DLHR REG8 (UART0_BASE + OFF_DLHR) #define UART0_IER REG8 (UART0_BASE + OFF_IER) #define UART0_ISR REG8 (UART0_BASE + OFF_ISR) #define UART0_FCR REG8 (UART0_BASE + OFF_FCR) #define UART0_LCR REG8 (UART0_BASE + OFF_LCR) #define UART0_MCR REG8 (UART0_BASE + OFF_MCR) #define UART0_LSR REG8 (UART0_BASE + OFF_LSR) #define UART0_MSR REG8 (UART0_BASE + OFF_MSR) #define UART0_SPR REG8 (UART0_BASE + OFF_SPR) #define UART0_SIRCR REG8 (UART0_BASE + OFF_SIRCR) #define UART0_UMR REG8 (UART0_BASE + OFF_UMR) #define UART0_UACR REG8 (UART0_BASE + OFF_UACR) // UART Interrupt Enable Register #define UARTIER_RIE (1 << 0) // 0: receive fifo full interrupt disable #define UARTIER_TIE (1 << 1) // 0: transmit fifo empty interrupt disable #define UARTIER_RLIE (1 << 2) // 0: receive line status interrupt disable #define UARTIER_MIE (1 << 3) // 0: modem status interrupt disable #define UARTIER_RTIE (1 << 4) // 0: receive timeout interrupt disable // UART Interrupt Status Register #define UARTISR_IP (1 << 0) // 0: interrupt is pending 1: no interrupt #define UARTISR_IID (7 << 1) // Source of Interrupt #define UARTISR_IID_MSI (0 << 1) // Modem status interrupt #define UARTISR_IID_THRI (1 << 1) // Transmitter holding register empty #define UARTISR_IID_RDI (2 << 1) // Receiver data interrupt #define UARTISR_IID_RLSI (3 << 1) // Receiver line status interrupt #define UARTISR_IID_RTO (6 << 1) // Receive timeout #define UARTISR_FFMS (3 << 6) // FIFO mode select, set when UARTFCR.FE is set to 1 #define UARTISR_FFMS_NO_FIFO (0 << 6) #define UARTISR_FFMS_FIFO_MODE (3 << 6) // UART FIFO Control Register #define UARTFCR_FE (1 << 0) // 0: non-FIFO mode 1: FIFO mode #define UARTFCR_RFLS (1 << 1) // write 1 to flush receive FIFO #define UARTFCR_TFLS (1 << 2) // write 1 to flush transmit FIFO #define UARTFCR_DMS (1 << 3) // 0: disable DMA mode #define UARTFCR_UUE (1 << 4) // 0: disable UART #define UARTFCR_RTRG (3 << 6) // Receive FIFO Data Trigger #define UARTFCR_RTRG_1 (0 << 6) #define UARTFCR_RTRG_4 (1 << 6) #define UARTFCR_RTRG_8 (2 << 6) #define UARTFCR_RTRG_15 (3 << 6) // UART Line Control Register #define UARTLCR_WLEN (3 << 0) // word length #define UARTLCR_WLEN_5 (0 << 0) #define UARTLCR_WLEN_6 (1 << 0) #define UARTLCR_WLEN_7 (2 << 0) #define UARTLCR_WLEN_8 (3 << 0) #define UARTLCR_STOP (1 << 2) // 0: 1 stop bit when word length is 5,6,7,8 1: 1.5 stop bits when 5; 2 stop bits when 6,7,8 #define UARTLCR_STOP1 (0 << 2) #define UARTLCR_STOP2 (1 << 2) #define UARTLCR_PE (1 << 3) // 0: parity disable #define UARTLCR_PROE (1 << 4) // 0: even parity 1: odd parity #define UARTLCR_SPAR (1 << 5) // 0: sticky parity disable #define UARTLCR_SBRK (1 << 6) // write 0 normal, write 1 send break #define UARTLCR_DLAB (1 << 7) // 0: access UARTRDR/TDR/IER 1: access UARTDLLR/DLHR // UART Line Status Register #define UARTLSR_DR (1 << 0) // 0: receive FIFO is empty 1: receive data is ready #define UARTLSR_ORER (1 << 1) // 0: no overrun error #define UARTLSR_PER (1 << 2) // 0: no parity error #define UARTLSR_FER (1 << 3) // 0; no framing error #define UARTLSR_BRK (1 << 4) // 0: no break detected 1: receive a break signal #define UARTLSR_TDRQ (1 << 5) // 1: transmit FIFO half "empty" #define UARTLSR_TEMT (1 << 6) // 1: transmit FIFO and shift registers empty #define UARTLSR_RFER (1 << 7) // 0: no receive error 1: receive error in FIFO mode // UART Modem Control Register #define UARTMCR_RTS (1 << 1) // 0: RTS_ output high, 1: RTS_ output low #define UARTMCR_LOOP (1 << 4) // 0: normal 1: loopback mode #define UARTMCR_MCE (1 << 7) // 0: modem function is disable // UART Modem Status Register #define UARTMSR_CCTS (1 << 0) // 1: a change on CTS_ pin #define UARTMSR_CTS (1 << 4) // 0: CTS_ pin is high // Slow IrDA Control Register #define SIRCR_TSIRE (1 << 0) // 0: transmitter is in UART mode 1: SIR mode #define SIRCR_RSIRE (1 << 1) // 0: receiver is in UART mode 1: SIR mode #define SIRCR_TPWS (1 << 2) // 0: transmit 0 pulse width is 3/16 of bit length 1: 0 pulse width is 1.6us for 115.2Kbps #define SIRCR_TDPL (1 << 3) // 0: encoder generates a positive pulse for 0 #define SIRCR_RDPL (1 << 4) // 0: decoder interprets positive pulse as 0 //************************************************************************ // AIC (AC97/I2S Controller) //************************************************************************ #define AIC_FR REG32 (AIC_BASE + 0x000) #define AIC_CR REG32 (AIC_BASE + 0x004) #define AIC_ACCR1 REG32 (AIC_BASE + 0x008) #define AIC_ACCR2 REG32 (AIC_BASE + 0x00C) #define AIC_I2SCR REG32 (AIC_BASE + 0x010) #define AIC_SR REG32 (AIC_BASE + 0x014) #define AIC_ACSR REG32 (AIC_BASE + 0x018) #define AIC_I2SSR REG32 (AIC_BASE + 0x01C) #define AIC_ACCAR REG32 (AIC_BASE + 0x020) #define AIC_ACCDR REG32 (AIC_BASE + 0x024) #define AIC_ACSAR REG32 (AIC_BASE + 0x028) #define AIC_ACSDR REG32 (AIC_BASE + 0x02C) #define AIC_I2SDIV REG32 (AIC_BASE + 0x030) #define AIC_DR REG32 (AIC_BASE + 0x034) // AIC Controller Configuration Register (AIC_FR) #define AIC_FR_RFTH_BIT 12 // Receive FIFO Threshold #define AIC_FR_RFTH_MASK (0xf << AIC_FR_RFTH_BIT) #define AIC_FR_TFTH_BIT 8 // Transmit FIFO Threshold #define AIC_FR_TFTH_MASK (0xf << AIC_FR_TFTH_BIT) #define AIC_FR_LSMP (1 << 6) // Play Zero sample or last sample #define AIC_FR_ICDC (1 << 5) // External(0) or Internal CODEC(1) #define AIC_FR_AUSEL (1 << 4) // AC97(0) or I2S/MSB-justified(1) #define AIC_FR_RST (1 << 3) // AIC registers reset #define AIC_FR_BCKD (1 << 2) // I2S BIT_CLK direction, 0:input,1:output #define AIC_FR_SYNCD (1 << 1) // I2S SYNC direction, 0:input,1:output #define AIC_FR_ENB (1 << 0) // AIC enable bit // AIC Controller Common Control Register (AIC_CR) #define AIC_CR_OSS_BIT 19 // Output Sample Size from memory (AIC V2 only) #define AIC_CR_OSS_MASK (0x7 << AIC_CR_OSS_BIT) #define AIC_CR_OSS_8BIT (0x0 << AIC_CR_OSS_BIT) #define AIC_CR_OSS_16BIT (0x1 << AIC_CR_OSS_BIT) #define AIC_CR_OSS_18BIT (0x2 << AIC_CR_OSS_BIT) #define AIC_CR_OSS_20BIT (0x3 << AIC_CR_OSS_BIT) #define AIC_CR_OSS_24BIT (0x4 << AIC_CR_OSS_BIT) #define AIC_CR_ISS_BIT 16 // Input Sample Size from memory (AIC V2 only) #define AIC_CR_ISS_MASK (0x7 << AIC_CR_ISS_BIT) #define AIC_CR_ISS_8BIT (0x0 << AIC_CR_ISS_BIT) #define AIC_CR_ISS_16BIT (0x1 << AIC_CR_ISS_BIT) #define AIC_CR_ISS_18BIT (0x2 << AIC_CR_ISS_BIT) #define AIC_CR_ISS_20BIT (0x3 << AIC_CR_ISS_BIT) #define AIC_CR_ISS_24BIT (0x4 << AIC_CR_ISS_BIT) #define AIC_CR_RDMS (1 << 15) // Receive DMA enable #define AIC_CR_TDMS (1 << 14) // Transmit DMA enable #define AIC_CR_M2S (1 << 11) // Mono to Stereo enable #define AIC_CR_ENDSW (1 << 10) // Endian switch enable #define AIC_CR_AVSTSU (1 << 9) // Signed <-> Unsigned toggle enable #define AIC_CR_FLUSH (1 << 8) // Flush FIFO #define AIC_CR_EROR (1 << 6) // Enable ROR interrupt #define AIC_CR_ETUR (1 << 5) // Enable TUR interrupt #define AIC_CR_ERFS (1 << 4) // Enable RFS interrupt #define AIC_CR_ETFS (1 << 3) // Enable TFS interrupt #define AIC_CR_ENLBF (1 << 2) // Enable Loopback Function #define AIC_CR_ERPL (1 << 1) // Enable Playback Function #define AIC_CR_EREC (1 << 0) // Enable Record Function // AIC Controller AC-link Control Register 1 (AIC_ACCR1) #define AIC_ACCR1_RS_BIT 16 // Receive Valid Slots #define AIC_ACCR1_RS_MASK (0x3ff << AIC_ACCR1_RS_BIT) #define AIC_ACCR1_RS_SLOT12 (1 << 25) // Slot 12 valid bit #define AIC_ACCR1_RS_SLOT11 (1 << 24) // Slot 11 valid bit #define AIC_ACCR1_RS_SLOT10 (1 << 23) // Slot 10 valid bit #define AIC_ACCR1_RS_SLOT9 (1 << 22) // Slot 9 valid bit, LFE #define AIC_ACCR1_RS_SLOT8 (1 << 21) // Slot 8 valid bit, Surround Right #define AIC_ACCR1_RS_SLOT7 (1 << 20) // Slot 7 valid bit, Surround Left #define AIC_ACCR1_RS_SLOT6 (1 << 19) // Slot 6 valid bit, PCM Center #define AIC_ACCR1_RS_SLOT5 (1 << 18) // Slot 5 valid bit #define AIC_ACCR1_RS_SLOT4 (1 << 17) // Slot 4 valid bit, PCM Right #define AIC_ACCR1_RS_SLOT3 (1 << 16) // Slot 3 valid bit, PCM Left #define AIC_ACCR1_XS_BIT 0 // Transmit Valid Slots #define AIC_ACCR1_XS_MASK (0x3ff << AIC_ACCR1_XS_BIT) #define AIC_ACCR1_XS_SLOT12 (1 << 9) // Slot 12 valid bit #define AIC_ACCR1_XS_SLOT11 (1 << 8) // Slot 11 valid bit #define AIC_ACCR1_XS_SLOT10 (1 << 7) // Slot 10 valid bit #define AIC_ACCR1_XS_SLOT9 (1 << 6) // Slot 9 valid bit, LFE #define AIC_ACCR1_XS_SLOT8 (1 << 5) // Slot 8 valid bit, Surround Right #define AIC_ACCR1_XS_SLOT7 (1 << 4) // Slot 7 valid bit, Surround Left #define AIC_ACCR1_XS_SLOT6 (1 << 3) // Slot 6 valid bit, PCM Center #define AIC_ACCR1_XS_SLOT5 (1 << 2) // Slot 5 valid bit #define AIC_ACCR1_XS_SLOT4 (1 << 1) // Slot 4 valid bit, PCM Right #define AIC_ACCR1_XS_SLOT3 (1 << 0) // Slot 3 valid bit, PCM Left // AIC Controller AC-link Control Register 2 (AIC_ACCR2) #define AIC_ACCR2_ERSTO (1 << 18) // Enable RSTO interrupt #define AIC_ACCR2_ESADR (1 << 17) // Enable SADR interrupt #define AIC_ACCR2_ECADT (1 << 16) // Enable CADT interrupt #define AIC_ACCR2_OASS_BIT 8 // Output Sample Size for AC-link #define AIC_ACCR2_OASS_MASK (0x3 << AIC_ACCR2_OASS_BIT) #define AIC_ACCR2_OASS_20BIT (0 << AIC_ACCR2_OASS_BIT) // Output Audio Sample Size is 20-bit #define AIC_ACCR2_OASS_18BIT (1 << AIC_ACCR2_OASS_BIT) // Output Audio Sample Size is 18-bit #define AIC_ACCR2_OASS_16BIT (2 << AIC_ACCR2_OASS_BIT) // Output Audio Sample Size is 16-bit #define AIC_ACCR2_OASS_8BIT (3 << AIC_ACCR2_OASS_BIT) // Output Audio Sample Size is 8-bit #define AIC_ACCR2_IASS_BIT 6 // Output Sample Size for AC-link #define AIC_ACCR2_IASS_MASK (0x3 << AIC_ACCR2_IASS_BIT) #define AIC_ACCR2_IASS_20BIT (0 << AIC_ACCR2_IASS_BIT) // Input Audio Sample Size is 20-bit #define AIC_ACCR2_IASS_18BIT (1 << AIC_ACCR2_IASS_BIT) // Input Audio Sample Size is 18-bit #define AIC_ACCR2_IASS_16BIT (2 << AIC_ACCR2_IASS_BIT) // Input Audio Sample Size is 16-bit #define AIC_ACCR2_IASS_8BIT (3 << AIC_ACCR2_IASS_BIT) // Input Audio Sample Size is 8-bit #define AIC_ACCR2_SO (1 << 3) // SDATA_OUT output value #define AIC_ACCR2_SR (1 << 2) // RESET# pin level #define AIC_ACCR2_SS (1 << 1) // SYNC pin level #define AIC_ACCR2_SA (1 << 0) // SYNC and SDATA_OUT alternation // AIC Controller I2S/MSB-justified Control Register (AIC_I2SCR) #define AIC_I2SCR_STPBK (1 << 12) // Stop BIT_CLK for I2S/MSB-justified #define AIC_I2SCR_WL_BIT 1 // Input/Output Sample Size for I2S/MSB-justified #define AIC_I2SCR_WL_MASK (0x7 << AIC_I2SCR_WL_BIT) #define AIC_I2SCR_WL_24BIT (0 << AIC_I2SCR_WL_BIT) // Word Length is 24 bit #define AIC_I2SCR_WL_20BIT (1 << AIC_I2SCR_WL_BIT) // Word Length is 20 bit #define AIC_I2SCR_WL_18BIT (2 << AIC_I2SCR_WL_BIT) // Word Length is 18 bit #define AIC_I2SCR_WL_16BIT (3 << AIC_I2SCR_WL_BIT) // Word Length is 16 bit #define AIC_I2SCR_WL_8BIT (4 << AIC_I2SCR_WL_BIT) // Word Length is 8 bit #define AIC_I2SCR_AMSL (1 << 0) // 0:I2S, 1:MSB-justified // AIC Controller FIFO Status Register (AIC_SR) #define AIC_SR_RFL_BIT 24 // Receive FIFO Level #define AIC_SR_RFL_MASK (0x3f << AIC_SR_RFL_BIT) #define AIC_SR_TFL_BIT 8 // Transmit FIFO level #define AIC_SR_TFL_MASK (0x3f << AIC_SR_TFL_BIT) #define AIC_SR_ROR (1 << 6) // Receive FIFO Overrun #define AIC_SR_TUR (1 << 5) // Transmit FIFO Underrun #define AIC_SR_RFS (1 << 4) // Receive FIFO Service Request #define AIC_SR_TFS (1 << 3) // Transmit FIFO Service Request // AIC Controller AC-link Status Register (AIC_ACSR) #define AIC_ACSR_SLTERR (1 << 21) // Slot Error Flag #define AIC_ACSR_CRDY (1 << 20) // External CODEC Ready Flag #define AIC_ACSR_CLPM (1 << 19) // External CODEC low power mode flag #define AIC_ACSR_RSTO (1 << 18) // External CODEC regs read status timeout #define AIC_ACSR_SADR (1 << 17) // External CODEC regs status addr and data received #define AIC_ACSR_CADT (1 << 16) // Command Address and Data Transmitted // AIC Controller I2S/MSB-justified Status Register (AIC_I2SSR) #define AIC_I2SSR_BSY (1 << 2) // AIC Busy in I2S/MSB-justified format // AIC Controller AC97 codec Command Address Register (AIC_ACCAR) #define AIC_ACCAR_CAR_BIT 0 #define AIC_ACCAR_CAR_MASK (0xfffff << AIC_ACCAR_CAR_BIT) // AIC Controller AC97 codec Command Data Register (AIC_ACCDR) #define AIC_ACCDR_CDR_BIT 0 #define AIC_ACCDR_CDR_MASK (0xfffff << AIC_ACCDR_CDR_BIT) // AIC Controller AC97 codec Status Address Register (AIC_ACSAR) #define AIC_ACSAR_SAR_BIT 0 #define AIC_ACSAR_SAR_MASK (0xfffff << AIC_ACSAR_SAR_BIT) // AIC Controller AC97 codec Status Data Register (AIC_ACSDR) #define AIC_ACSDR_SDR_BIT 0 #define AIC_ACSDR_SDR_MASK (0xfffff << AIC_ACSDR_SDR_BIT) // AIC Controller I2S/MSB-justified Clock Divider Register (AIC_I2SDIV) #define AIC_I2SDIV_DIV_BIT 0 #define AIC_I2SDIV_DIV_MASK (0x7f << AIC_I2SDIV_DIV_BIT) #define AIC_I2SDIV_BITCLK_3072KHZ (0x0C << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 3.072MHz #define AIC_I2SDIV_BITCLK_2836KHZ (0x0D << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 2.836MHz #define AIC_I2SDIV_BITCLK_1418KHZ (0x1A << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 1.418MHz #define AIC_I2SDIV_BITCLK_1024KHZ (0x24 << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 1.024MHz #define AIC_I2SDIV_BITCLK_7089KHZ (0x34 << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 708.92KHz #define AIC_I2SDIV_BITCLK_512KHZ (0x48 << AIC_I2SDIV_DIV_BIT) // BIT_CLK of 512.00KHz //************************************************************************ // ICDC (Internal CODEC) //************************************************************************ #define ICDC_CR REG32 (ICDC_BASE + 0x0400) // ICDC Control Register #define ICDC_APWAIT REG32 (ICDC_BASE + 0x0404) // Anti-Pop WAIT Stage Timing Control Register #define ICDC_APPRE REG32 (ICDC_BASE + 0x0408) // Anti-Pop HPEN-PRE Stage Timing Control Register #define ICDC_APHPEN REG32 (ICDC_BASE + 0x040C) // Anti-Pop HPEN Stage Timing Control Register #define ICDC_APSR REG32 (ICDC_BASE + 0x0410) // Anti-Pop Status Register #define ICDC_CDCCR1 REG32 (ICDC_BASE + 0x0080) #define ICDC_CDCCR2 REG32 (ICDC_BASE + 0x0084) // ICDC Control Register #define ICDC_CR_LINVOL_BIT 24 // LINE Input Volume Gain: GAIN=LINVOL*1.5-34.5 #define ICDC_CR_LINVOL_MASK (0x1f << ICDC_CR_LINVOL_BIT) #define ICDC_CR_ASRATE_BIT 20 // Audio Sample Rate #define ICDC_CR_ASRATE_MASK (0x0f << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_8000 (0x0 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_11025 (0x1 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_12000 (0x2 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_16000 (0x3 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_22050 (0x4 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_24000 (0x5 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_32000 (0x6 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_44100 (0x7 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_ASRATE_48000 (0x8 << ICDC_CR_ASRATE_BIT) #define ICDC_CR_MICBG_BIT 18 // MIC Boost Gain #define ICDC_CR_MICBG_MASK (0x3 << ICDC_CR_MICBG_BIT) #define ICDC_CR_MICBG_0DB (0x0 << ICDC_CR_MICBG_BIT) #define ICDC_CR_MICBG_6DB (0x1 << ICDC_CR_MICBG_BIT) #define ICDC_CR_MICBG_12DB (0x2 << ICDC_CR_MICBG_BIT) #define ICDC_CR_MICBG_20DB (0x3 << ICDC_CR_MICBG_BIT) #define ICDC_CR_HPVOL_BIT 16 // Headphone Volume Gain #define ICDC_CR_HPVOL_MASK (0x3 << ICDC_CR_HPVOL_BIT) #define ICDC_CR_HPVOL_0DB (0x0 << ICDC_CR_HPVOL_BIT) #define ICDC_CR_HPVOL_2DB (0x1 << ICDC_CR_HPVOL_BIT) #define ICDC_CR_HPVOL_4DB (0x2 << ICDC_CR_HPVOL_BIT) #define ICDC_CR_HPVOL_6DB (0x3 << ICDC_CR_HPVOL_BIT) #define ICDC_CR_ELINEIN (1 << 13) // Enable LINE Input #define ICDC_CR_EMIC (1 << 12) // Enable MIC Input #define ICDC_CR_SW1ON (1 << 11) // Switch 1 in CODEC is on #define ICDC_CR_EADC (1 << 10) // Enable ADC #define ICDC_CR_SW2ON (1 << 9) // Switch 2 in CODEC is on #define ICDC_CR_EDAC (1 << 8) // Enable DAC #define ICDC_CR_HPMUTE (1 << 5) // Headphone Mute #define ICDC_CR_HPTON (1 << 4) // Headphone Amplifier Trun On #define ICDC_CR_HPTOFF (1 << 3) // Headphone Amplifier Trun Off #define ICDC_CR_TAAP (1 << 2) // Turn Around of the Anti-Pop Procedure #define ICDC_CR_EAP (1 << 1) // Enable Anti-Pop Procedure #define ICDC_CR_SUSPD (1 << 0) // CODEC Suspend // Anti-Pop WAIT Stage Timing Control Register #define ICDC_APWAIT_WAITSN_BIT 0 #define ICDC_APWAIT_WAITSN_MASK (0x7ff << ICDC_APWAIT_WAITSN_BIT) // Anti-Pop HPEN-PRE Stage Timing Control Register #define ICDC_APPRE_PRESN_BIT 0 #define ICDC_APPRE_PRESN_MASK (0x1ff << ICDC_APPRE_PRESN_BIT) // Anti-Pop HPEN Stage Timing Control Register #define ICDC_APHPEN_HPENSN_BIT 0 #define ICDC_APHPEN_HPENSN_MASK (0x3fff << ICDC_APHPEN_HPENSN_BIT) // Anti-Pop Status Register #define ICDC_SR_HPST_BIT 14 // Headphone Amplifier State #define ICDC_SR_HPST_MASK (0x7 << ICDC_SR_HPST_BIT) #define ICDC_SR_HPST_HP_OFF (0x0 << ICDC_SR_HPST_BIT) // HP amplifier is off #define ICDC_SR_HPST_TON_WAIT (0x1 << ICDC_SR_HPST_BIT) // wait state in turn-on #define ICDC_SR_HPST_TON_PRE (0x2 << ICDC_SR_HPST_BIT) // pre-enable state in turn-on #define ICDC_SR_HPST_TON_HPEN (0x3 << ICDC_SR_HPST_BIT) // HP enable state in turn-on #define ICDC_SR_HPST_TOFF_HPEN (0x4 << ICDC_SR_HPST_BIT) // HP enable state in turn-off #define ICDC_SR_HPST_TOFF_PRE (0x5 << ICDC_SR_HPST_BIT) // pre-enable state in turn-off #define ICDC_SR_HPST_TOFF_WAIT (0x6 << ICDC_SR_HPST_BIT) // wait state in turn-off #define ICDC_SR_HPST_HP_ON (0x7 << ICDC_SR_HPST_BIT) // HP amplifier is on #define ICDC_SR_SNCNT_BIT 0 // Sample Number Counter #define ICDC_SR_SNCNT_MASK (0x3fff << ICDC_SR_SNCNT_BIT) //************************************************************************ // I2C //************************************************************************ #define I2C_DR REG8 (I2C_BASE + 0x000) #define I2C_CR REG8 (I2C_BASE + 0x004) #define I2C_SR REG8 (I2C_BASE + 0x008) #define I2C_GR REG16 (I2C_BASE + 0x00C) // I2C Control Register (I2C_CR) #define I2C_CR_IEN (1 << 4) #define I2C_CR_STA (1 << 3) #define I2C_CR_STO (1 << 2) #define I2C_CR_AC (1 << 1) #define I2C_CR_I2CE (1 << 0) // I2C Status Register (I2C_SR) #define I2C_SR_STX (1 << 4) #define I2C_SR_BUSY (1 << 3) #define I2C_SR_TEND (1 << 2) #define I2C_SR_DRF (1 << 1) #define I2C_SR_ACKF (1 << 0) //************************************************************************ // SSI //************************************************************************ #define SSI_DR REG32 (SSI_BASE + 0x000) #define SSI_CR0 REG16 (SSI_BASE + 0x004) #define SSI_CR1 REG32 (SSI_BASE + 0x008) #define SSI_SR REG32 (SSI_BASE + 0x00C) #define SSI_ITR REG16 (SSI_BASE + 0x010) #define SSI_ICR REG8 (SSI_BASE + 0x014) #define SSI_GR REG16 (SSI_BASE + 0x018) // SSI Data Register (SSI_DR) #define SSI_DR_GPC_BIT 0 #define SSI_DR_GPC_MASK (0x1ff << SSI_DR_GPC_BIT) // SSI Control Register 0 (SSI_CR0) #define SSI_CR0_SSIE (1 << 15) #define SSI_CR0_TIE (1 << 14) #define SSI_CR0_RIE (1 << 13) #define SSI_CR0_TEIE (1 << 12) #define SSI_CR0_REIE (1 << 11) #define SSI_CR0_LOOP (1 << 10) #define SSI_CR0_RFINE (1 << 9) #define SSI_CR0_RFINC (1 << 8) #define SSI_CR0_FSEL (1 << 6) #define SSI_CR0_TFLUSH (1 << 2) #define SSI_CR0_RFLUSH (1 << 1) #define SSI_CR0_DISREV (1 << 0) // SSI Control Register 1 (SSI_CR1) #define SSI_CR1_FRMHL_BIT 30 #define SSI_CR1_FRMHL_MASK (0x3 << SSI_CR1_FRMHL_BIT) #define SSI_CR1_FRMHL_CELOW_CE2LOW (0 << SSI_CR1_FRMHL_BIT) // SSI_CE_ is low valid and SSI_CE2_ is low valid #define SSI_CR1_FRMHL_CEHIGH_CE2LOW (1 << SSI_CR1_FRMHL_BIT) // SSI_CE_ is high valid and SSI_CE2_ is low valid #define SSI_CR1_FRMHL_CELOW_CE2HIGH (2 << SSI_CR1_FRMHL_BIT) // SSI_CE_ is low valid and SSI_CE2_ is high valid #define SSI_CR1_FRMHL_CEHIGH_CE2HIGH (3 << SSI_CR1_FRMHL_BIT) // SSI_CE_ is high valid and SSI_CE2_ is high valid #define SSI_CR1_TFVCK_BIT 28 #define SSI_CR1_TFVCK_MASK (0x3 << SSI_CR1_TFVCK_BIT) #define SSI_CR1_TFVCK_0 (0 << SSI_CR1_TFVCK_BIT) #define SSI_CR1_TFVCK_1 (1 << SSI_CR1_TFVCK_BIT) #define SSI_CR1_TFVCK_2 (2 << SSI_CR1_TFVCK_BIT) #define SSI_CR1_TFVCK_3 (3 << SSI_CR1_TFVCK_BIT) #define SSI_CR1_TCKFI_BIT 26 #define SSI_CR1_TCKFI_MASK (0x3 << SSI_CR1_TCKFI_BIT) #define SSI_CR1_TCKFI_0 (0 << SSI_CR1_TCKFI_BIT) #define SSI_CR1_TCKFI_1 (1 << SSI_CR1_TCKFI_BIT) #define SSI_CR1_TCKFI_2 (2 << SSI_CR1_TCKFI_BIT) #define SSI_CR1_TCKFI_3 (3 << SSI_CR1_TCKFI_BIT) #define SSI_CR1_LFST (1 << 25) #define SSI_CR1_ITFRM (1 << 24) #define SSI_CR1_UNFIN (1 << 23) #define SSI_CR1_MULTS (1 << 22) #define SSI_CR1_FMAT_BIT 20 #define SSI_CR1_FMAT_MASK (0x3 << SSI_CR1_FMAT_BIT) #define SSI_CR1_FMAT_SPI (0 << SSI_CR1_FMAT_BIT) // Motorola's SPI format #define SSI_CR1_FMAT_SSP (1 << SSI_CR1_FMAT_BIT) // TI's SSP format #define SSI_CR1_FMAT_MW1 (2 << SSI_CR1_FMAT_BIT) // National Microwire 1 format #define SSI_CR1_FMAT_MW2 (3 << SSI_CR1_FMAT_BIT) // National Microwire 2 format #define SSI_CR1_TTRG_BIT 16 #define SSI_CR1_TTRG_MASK (0xf << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_1 (0 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_8 (1 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_16 (2 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_24 (3 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_32 (4 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_40 (5 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_48 (6 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_56 (7 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_64 (8 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_72 (9 << SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_80 (10<< SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_88 (11<< SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_96 (12<< SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_104 (13<< SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_112 (14<< SSI_CR1_TTRG_BIT) #define SSI_CR1_TTRG_120 (15<< SSI_CR1_TTRG_BIT) #define SSI_CR1_MCOM_BIT 12 #define SSI_CR1_MCOM_MASK (0xf << SSI_CR1_MCOM_BIT) #define SSI_CR1_MCOM_1BIT (0x0 << SSI_CR1_MCOM_BIT) // 1-bit command selected #define SSI_CR1_MCOM_2BIT (0x1 << SSI_CR1_MCOM_BIT) // 2-bit command selected #define SSI_CR1_MCOM_3BIT (0x2 << SSI_CR1_MCOM_BIT) // 3-bit command selected #define SSI_CR1_MCOM_4BIT (0x3 << SSI_CR1_MCOM_BIT) // 4-bit command selected #define SSI_CR1_MCOM_5BIT (0x4 << SSI_CR1_MCOM_BIT) // 5-bit command selected #define SSI_CR1_MCOM_6BIT (0x5 << SSI_CR1_MCOM_BIT) // 6-bit command selected #define SSI_CR1_MCOM_7BIT (0x6 << SSI_CR1_MCOM_BIT) // 7-bit command selected #define SSI_CR1_MCOM_8BIT (0x7 << SSI_CR1_MCOM_BIT) // 8-bit command selected #define SSI_CR1_MCOM_9BIT (0x8 << SSI_CR1_MCOM_BIT) // 9-bit command selected #define SSI_CR1_MCOM_10BIT (0x9 << SSI_CR1_MCOM_BIT) // 10-bit command selected #define SSI_CR1_MCOM_11BIT (0xA << SSI_CR1_MCOM_BIT) // 11-bit command selected #define SSI_CR1_MCOM_12BIT (0xB << SSI_CR1_MCOM_BIT) // 12-bit command selected #define SSI_CR1_MCOM_13BIT (0xC << SSI_CR1_MCOM_BIT) // 13-bit command selected #define SSI_CR1_MCOM_14BIT (0xD << SSI_CR1_MCOM_BIT) // 14-bit command selected #define SSI_CR1_MCOM_15BIT (0xE << SSI_CR1_MCOM_BIT) // 15-bit command selected #define SSI_CR1_MCOM_16BIT (0xF << SSI_CR1_MCOM_BIT) // 16-bit command selected #define SSI_CR1_RTRG_BIT 8 #define SSI_CR1_RTRG_MASK (0xf << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_1 (0 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_8 (1 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_16 (2 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_24 (3 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_32 (4 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_40 (5 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_48 (6 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_56 (7 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_64 (8 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_72 (9 << SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_80 (10<< SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_88 (11<< SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_96 (12<< SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_104 (13<< SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_112 (14<< SSI_CR1_RTRG_BIT) #define SSI_CR1_RTRG_120 (15<< SSI_CR1_RTRG_BIT) #define SSI_CR1_FLEN_BIT 4 #define SSI_CR1_FLEN_MASK (0xf << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_2BIT (0x0 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_3BIT (0x1 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_4BIT (0x2 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_5BIT (0x3 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_6BIT (0x4 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_7BIT (0x5 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_8BIT (0x6 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_9BIT (0x7 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_10BIT (0x8 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_11BIT (0x9 << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_12BIT (0xA << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_13BIT (0xB << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_14BIT (0xC << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_15BIT (0xD << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_16BIT (0xE << SSI_CR1_FLEN_BIT) #define SSI_CR1_FLEN_17BIT (0xF << SSI_CR1_FLEN_BIT) #define SSI_CR1_PHA (1 << 1) #define SSI_CR1_POL (1 << 0) // SSI Status Register (SSI_SR) #define SSI_SR_TFIFONUM_BIT 16 #define SSI_SR_TFIFONUM_MASK (0xff << SSI_SR_TFIFONUM_BIT) #define SSI_SR_RFIFONUM_BIT 8 #define SSI_SR_RFIFONUM_MASK (0xff << SSI_SR_RFIFONUM_BIT) #define SSI_SR_END (1 << 7) #define SSI_SR_BUSY (1 << 6) #define SSI_SR_TFF (1 << 5) #define SSI_SR_RFE (1 << 4) #define SSI_SR_TFHE (1 << 3) #define SSI_SR_RFHF (1 << 2) #define SSI_SR_UNDR (1 << 1) #define SSI_SR_OVER (1 << 0) // SSI Interval Time Control Register (SSI_ITR) #define SSI_ITR_CNTCLK (1 << 15) #define SSI_ITR_IVLTM_BIT 0 #define SSI_ITR_IVLTM_MASK (0x7fff << SSI_ITR_IVLTM_BIT) //************************************************************************ // MSC //************************************************************************ #define MSC_STRPCL REG16 (MSC_BASE + 0x000) #define MSC_STAT REG32 (MSC_BASE + 0x004) #define MSC_CLKRT REG16 (MSC_BASE + 0x008) #define MSC_CMDAT REG32 (MSC_BASE + 0x00C) #define MSC_RESTO REG16 (MSC_BASE + 0x010) #define MSC_RDTO REG16 (MSC_BASE + 0x014) #define MSC_BLKLEN REG16 (MSC_BASE + 0x018) #define MSC_NOB REG16 (MSC_BASE + 0x01C) #define MSC_SNOB REG16 (MSC_BASE + 0x020) #define MSC_IMASK REG16 (MSC_BASE + 0x024) #define MSC_IREG REG16 (MSC_BASE + 0x028) #define MSC_CMD REG8 (MSC_BASE + 0x02C) #define MSC_ARG REG32 (MSC_BASE + 0x030) #define MSC_RES REG16 (MSC_BASE + 0x034) #define MSC_RXFIFO REG32 (MSC_BASE + 0x038) #define MSC_TXFIFO REG32 (MSC_BASE + 0x03C) // MSC Clock and Control Register (MSC_STRPCL) #define MSC_STRPCL_EXIT_MULTIPLE (1 << 7) #define MSC_STRPCL_EXIT_TRANSFER (1 << 6) #define MSC_STRPCL_START_READWAIT (1 << 5) #define MSC_STRPCL_STOP_READWAIT (1 << 4) #define MSC_STRPCL_RESET (1 << 3) #define MSC_STRPCL_START_OP (1 << 2) #define MSC_STRPCL_CLOCK_CONTROL_BIT 0 #define MSC_STRPCL_CLOCK_CONTROL_MASK (0x3 << MSC_STRPCL_CLOCK_CONTROL_BIT) #define MSC_STRPCL_CLOCK_CONTROL_STOP (0x1 << MSC_STRPCL_CLOCK_CONTROL_BIT) // Stop MMC/SD clock #define MSC_STRPCL_CLOCK_CONTROL_START (0x2 << MSC_STRPCL_CLOCK_CONTROL_BIT) // Start MMC/SD clock // MSC Status Register (MSC_STAT) #define MSC_STAT_IS_RESETTING (1 << 15) #define MSC_STAT_SDIO_INT_ACTIVE (1 << 14) #define MSC_STAT_PRG_DONE (1 << 13) #define MSC_STAT_DATA_TRAN_DONE (1 << 12) #define MSC_STAT_END_CMD_RES (1 << 11) #define MSC_STAT_DATA_FIFO_AFULL (1 << 10) #define MSC_STAT_IS_READWAIT (1 << 9) #define MSC_STAT_CLK_EN (1 << 8) #define MSC_STAT_DATA_FIFO_FULL (1 << 7) #define MSC_STAT_DATA_FIFO_EMPTY (1 << 6) #define MSC_STAT_CRC_RES_ERR (1 << 5) #define MSC_STAT_CRC_READ_ERROR (1 << 4) #define MSC_STAT_CRC_WRITE_ERROR_BIT 2 #define MSC_STAT_CRC_WRITE_ERROR_MASK (0x3 << MSC_STAT_CRC_WRITE_ERROR_BIT) #define MSC_STAT_CRC_WRITE_ERROR_NO (0 << MSC_STAT_CRC_WRITE_ERROR_BIT) // No error on transmission of data #define MSC_STAT_CRC_WRITE_ERROR (1 << MSC_STAT_CRC_WRITE_ERROR_BIT) // Card observed erroneous transmission of data #define MSC_STAT_CRC_WRITE_ERROR_NOSTS (2 << MSC_STAT_CRC_WRITE_ERROR_BIT) // No CRC status is sent back #define MSC_STAT_TIME_OUT_RES (1 << 1) #define MSC_STAT_TIME_OUT_READ (1 << 0) // MSC Bus Clock Control Register (MSC_CLKRT) #define MSC_CLKRT_CLK_RATE_BIT 0 #define MSC_CLKRT_CLK_RATE_MASK (0x7 << MSC_CLKRT_CLK_RATE_BIT) #define MSC_CLKRT_CLK_RATE_DIV_1 (0x0 << MSC_CLKRT_CLK_RATE_BIT) // CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_2 (0x1 << MSC_CLKRT_CLK_RATE_BIT) // 1/2 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_4 (0x2 << MSC_CLKRT_CLK_RATE_BIT) // 1/4 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_8 (0x3 << MSC_CLKRT_CLK_RATE_BIT) // 1/8 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_16 (0x4 << MSC_CLKRT_CLK_RATE_BIT) // 1/16 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_32 (0x5 << MSC_CLKRT_CLK_RATE_BIT) // 1/32 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_64 (0x6 << MSC_CLKRT_CLK_RATE_BIT) // 1/64 of CLK_SRC #define MSC_CLKRT_CLK_RATE_DIV_128 (0x7 << MSC_CLKRT_CLK_RATE_BIT) // 1/128 of CLK_SRC // MSC Command Sequence Control Register (MSC_CMDAT) #define MSC_CMDAT_IO_ABORT (1 << 11) #define MSC_CMDAT_BUS_WIDTH_BIT 9 #define MSC_CMDAT_BUS_WIDTH_MASK (0x3 << MSC_CMDAT_BUS_WIDTH_BIT) #define MSC_CMDAT_BUS_WIDTH_1BIT (0x0 << MSC_CMDAT_BUS_WIDTH_BIT) // 1-bit data bus #define MSC_CMDAT_BUS_WIDTH_4BIT (0x2 << MSC_CMDAT_BUS_WIDTH_BIT) // 4-bit data bus #define MSC_CMDAT_DMA_EN (1 << 8) #define MSC_CMDAT_INIT (1 << 7) #define MSC_CMDAT_BUSY (1 << 6) #define MSC_CMDAT_STREAM_BLOCK (1 << 5) #define MSC_CMDAT_WRITE (1 << 4) #define MSC_CMDAT_READ (0 << 4) #define MSC_CMDAT_DATA_EN (1 << 3) #define MSC_CMDAT_RESPONSE_BIT 0 #define MSC_CMDAT_RESPONSE_MASK (0x7 << MSC_CMDAT_RESPONSE_BIT) #define MSC_CMDAT_RESPONSE_NONE (0x0 << MSC_CMDAT_RESPONSE_BIT) // No response #define MSC_CMDAT_RESPONSE_R1 (0x1 << MSC_CMDAT_RESPONSE_BIT) // Format R1 and R1b #define MSC_CMDAT_RESPONSE_R2 (0x2 << MSC_CMDAT_RESPONSE_BIT) // Format R2 #define MSC_CMDAT_RESPONSE_R3 (0x3 << MSC_CMDAT_RESPONSE_BIT) // Format R3 #define MSC_CMDAT_RESPONSE_R4 (0x4 << MSC_CMDAT_RESPONSE_BIT) // Format R4 #define MSC_CMDAT_RESPONSE_R5 (0x5 << MSC_CMDAT_RESPONSE_BIT) // Format R5 #define MSC_CMDAT_RESPONSE_R6 (0x6 << MSC_CMDAT_RESPONSE_BIT) // Format R6 #define MSC_CMDAT_RESPONSE_R7 (0x7 << MSC_CMDAT_RESPONSE_BIT) // Format R7 #define MSC_CMDAT_DMA_EN (1 << 8) #define MSC_CMDAT_INIT (1 << 7) #define MSC_CMDAT_BUSY (1 << 6) #define MSC_CMDAT_STREAM (1 << 5) #define MSC_CMDAT_WRITE (1 << 4) #define MSC_CMDAT_DATA_EN (1 << 3) // MSC Interrupts Mask Register (MSC_IMASK) #define MSC_IMASK_SDIO (1 << 7) #define MSC_IMASK_TXFIFO_WR_REQ (1 << 6) #define MSC_IMASK_RXFIFO_RD_REQ (1 << 5) #define MSC_IMASK_END_CMD_RES (1 << 2) #define MSC_IMASK_PRG_DONE (1 << 1) #define MSC_IMASK_DATA_TRAN_DONE (1 << 0) // MSC Interrupts Status Register (MSC_IREG) #define MSC_IREG_SDIO (1 << 7) #define MSC_IREG_TXFIFO_WR_REQ (1 << 6) #define MSC_IREG_RXFIFO_RD_REQ (1 << 5) #define MSC_IREG_END_CMD_RES (1 << 2) #define MSC_IREG_PRG_DONE (1 << 1) #define MSC_IREG_DATA_TRAN_DONE (1 << 0) //************************************************************************ // EMC (External Memory Controller) //************************************************************************ #define EMC_SMCR(n) REG32 (EMC_BASE + 0x10 + 4 * (n)) // Static Memory Control Register n (n = 0,1,2,3,4) #define EMC_SACR(n) REG32 (EMC_BASE + 0x30 + 4 * (n)) // Static Memory Bank n Addr Config Reg (n = 0,1,2,3,4) #define EMC_NFCSR REG32 (EMC_BASE + 0x050) // NAND Flash Control/Status Register #define EMC_NFECR REG32 (EMC_BASE + 0x100) // NAND Flash ECC Control Register #define EMC_NFECC REG32 (EMC_BASE + 0x104) // NAND Flash ECC Data Register #define EMC_NFPAR(n) REG32 (EMC_BASE + 0x108 + 4 * (n)) // NAND Flash RS Parity n Register (n = 0,1,2) #define EMC_NFINTS REG32 (EMC_BASE + 0x114) // NAND Flash Interrupt Status Register #define EMC_NFINTE REG32 (EMC_BASE + 0x118) // NAND Flash Interrupt Enable Register #define EMC_NFERR(n) REG32 (EMC_BASE + 0x11c + 4 * (n)) // NAND Flash RS Error Report n Register (n = 0,1,2,3) #define EMC_DMCR REG32 (EMC_BASE + 0x80) // DRAM Control Register #define EMC_RTCSR REG16 (EMC_BASE + 0x84) // Refresh Time Control/Status Register #define EMC_RTCNT REG16 (EMC_BASE + 0x88) // Refresh Timer Counter #define EMC_RTCOR REG16 (EMC_BASE + 0x8c) // Refresh Time Constant Register #define EMC_DMAR0 REG32 (EMC_BASE + 0x90) // SDRAM Bank 0 Addr Config Register #define EMC_SDMR0 (EMC_BASE + 0xa000) // Mode Register of SDRAM bank 0. Very weird: uses address bus for data. Data bus is ignored, thus no REG #define EMC_BCR REG32 (EMC_BASE + 0x00) // Bus Control Register // Static Memory Control Register #define EMC_SMCR_STRV_BIT 24 #define EMC_SMCR_STRV_MASK (0x0f << EMC_SMCR_STRV_BIT) #define EMC_SMCR_TAW_BIT 20 #define EMC_SMCR_TAW_MASK (0x0f << EMC_SMCR_TAW_BIT) #define EMC_SMCR_TBP_BIT 16 #define EMC_SMCR_TBP_MASK (0x0f << EMC_SMCR_TBP_BIT) #define EMC_SMCR_TAH_BIT 12 #define EMC_SMCR_TAH_MASK (0x07 << EMC_SMCR_TAH_BIT) #define EMC_SMCR_TAS_BIT 8 #define EMC_SMCR_TAS_MASK (0x07 << EMC_SMCR_TAS_BIT) #define EMC_SMCR_BW_BIT 6 #define EMC_SMCR_BW_MASK (0x03 << EMC_SMCR_BW_BIT) #define EMC_SMCR_BW_8BIT (0 << EMC_SMCR_BW_BIT) #define EMC_SMCR_BW_16BIT (1 << EMC_SMCR_BW_BIT) #define EMC_SMCR_BW_32BIT (2 << EMC_SMCR_BW_BIT) #define EMC_SMCR_BCM (1 << 3) #define EMC_SMCR_BL_BIT 1 #define EMC_SMCR_BL_MASK (0x03 << EMC_SMCR_BL_BIT) #define EMC_SMCR_BL_4 (0 << EMC_SMCR_BL_BIT) #define EMC_SMCR_BL_8 (1 << EMC_SMCR_BL_BIT) #define EMC_SMCR_BL_16 (2 << EMC_SMCR_BL_BIT) #define EMC_SMCR_BL_32 (3 << EMC_SMCR_BL_BIT) #define EMC_SMCR_SMT (1 << 0) // Static Memory Bank Addr Config Reg #define EMC_SACR_BASE_BIT 8 #define EMC_SACR_BASE_MASK (0xff << EMC_SACR_BASE_BIT) #define EMC_SACR_MASK_BIT 0 #define EMC_SACR_MASK_MASK (0xff << EMC_SACR_MASK_BIT) // NAND Flash Control/Status Register #define EMC_NFCSR_NFCE4 (1 << 7) // NAND Flash Enable #define EMC_NFCSR_NFE4 (1 << 6) // NAND Flash FCE# Assertion Enable #define EMC_NFCSR_NFCE3 (1 << 5) #define EMC_NFCSR_NFE3 (1 << 4) #define EMC_NFCSR_NFCE2 (1 << 3) #define EMC_NFCSR_NFE2 (1 << 2) #define EMC_NFCSR_NFCE1 (1 << 1) #define EMC_NFCSR_NFE1 (1 << 0) // NAND Flash ECC Control Register #define EMC_NFECR_PRDY (1 << 4) // Parity Ready #define EMC_NFECR_RS_DECODING (0 << 3) // RS is in decoding phase #define EMC_NFECR_RS_ENCODING (1 << 3) // RS is in encoding phase #define EMC_NFECR_HAMMING (0 << 2) // Select HAMMING Correction Algorithm #define EMC_NFECR_RS (1 << 2) // Select RS Correction Algorithm #define EMC_NFECR_ERST (1 << 1) // ECC Reset #define EMC_NFECR_ECCE (1 << 0) // ECC Enable // NAND Flash ECC Data Register #define EMC_NFECC_ECC2_BIT 16 #define EMC_NFECC_ECC2_MASK (0xff << EMC_NFECC_ECC2_BIT) #define EMC_NFECC_ECC1_BIT 8 #define EMC_NFECC_ECC1_MASK (0xff << EMC_NFECC_ECC1_BIT) #define EMC_NFECC_ECC0_BIT 0 #define EMC_NFECC_ECC0_MASK (0xff << EMC_NFECC_ECC0_BIT) // NAND Flash Interrupt Status Register #define EMC_NFINTS_ERRCNT_BIT 29 // Error Count #define EMC_NFINTS_ERRCNT_MASK (0x7 << EMC_NFINTS_ERRCNT_BIT) #define EMC_NFINTS_PADF (1 << 4) // Padding Finished #define EMC_NFINTS_DECF (1 << 3) // Decoding Finished #define EMC_NFINTS_ENCF (1 << 2) // Encoding Finished #define EMC_NFINTS_UNCOR (1 << 1) // Uncorrectable Error Occurred #define EMC_NFINTS_ERR (1 << 0) // Error Occurred // NAND Flash Interrupt Enable Register #define EMC_NFINTE_PADFE (1 << 4) // Padding Finished Interrupt Enable #define EMC_NFINTE_DECFE (1 << 3) // Decoding Finished Interrupt Enable #define EMC_NFINTE_ENCFE (1 << 2) // Encoding Finished Interrupt Enable #define EMC_NFINTE_UNCORE (1 << 1) // Uncorrectable Error Occurred Intr Enable #define EMC_NFINTE_ERRE (1 << 0) // Error Occurred Interrupt // NAND Flash RS Error Report Register #define EMC_NFERR_INDEX_BIT 16 // Error Symbol Index #define EMC_NFERR_INDEX_MASK (0x1ff << EMC_NFERR_INDEX_BIT) #define EMC_NFERR_MASK_BIT 0 // Error Symbol Value #define EMC_NFERR_MASK_MASK (0x1ff << EMC_NFERR_MASK_BIT) // DRAM Control Register #define EMC_DMCR_BW_BIT 31 #define EMC_DMCR_BW (1 << EMC_DMCR_BW_BIT) #define EMC_DMCR_CA_BIT 26 #define EMC_DMCR_CA_MASK (0x07 << EMC_DMCR_CA_BIT) #define EMC_DMCR_CA_8 (0 << EMC_DMCR_CA_BIT) #define EMC_DMCR_CA_9 (1 << EMC_DMCR_CA_BIT) #define EMC_DMCR_CA_10 (2 << EMC_DMCR_CA_BIT) #define EMC_DMCR_CA_11 (3 << EMC_DMCR_CA_BIT) #define EMC_DMCR_CA_12 (4 << EMC_DMCR_CA_BIT) #define EMC_DMCR_RMODE (1 << 25) #define EMC_DMCR_RFSH (1 << 24) #define EMC_DMCR_MRSET (1 << 23) #define EMC_DMCR_RA_BIT 20 #define EMC_DMCR_RA_MASK (0x03 << EMC_DMCR_RA_BIT) #define EMC_DMCR_RA_11 (0 << EMC_DMCR_RA_BIT) #define EMC_DMCR_RA_12 (1 << EMC_DMCR_RA_BIT) #define EMC_DMCR_RA_13 (2 << EMC_DMCR_RA_BIT) #define EMC_DMCR_BA_BIT 19 #define EMC_DMCR_BA (1 << EMC_DMCR_BA_BIT) #define EMC_DMCR_PDM (1 << 18) #define EMC_DMCR_EPIN (1 << 17) #define EMC_DMCR_TRAS_BIT 13 #define EMC_DMCR_TRAS_MASK (0x07 << EMC_DMCR_TRAS_BIT) #define EMC_DMCR_RCD_BIT 11 #define EMC_DMCR_RCD_MASK (0x03 << EMC_DMCR_RCD_BIT) #define EMC_DMCR_TPC_BIT 8 #define EMC_DMCR_TPC_MASK (0x07 << EMC_DMCR_TPC_BIT) #define EMC_DMCR_TRWL_BIT 5 #define EMC_DMCR_TRWL_MASK (0x03 << EMC_DMCR_TRWL_BIT) #define EMC_DMCR_TRC_BIT 2 #define EMC_DMCR_TRC_MASK (0x07 << EMC_DMCR_TRC_BIT) #define EMC_DMCR_TCL_BIT 0 #define EMC_DMCR_TCL_MASK (0x03 << EMC_DMCR_TCL_BIT) // Refresh Time Control/Status Register #define EMC_RTCSR_CMF (1 << 7) #define EMC_RTCSR_CKS_BIT 0 #define EMC_RTCSR_CKS_MASK (0x07 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_DISABLE (0 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_4 (1 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_16 (2 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_64 (3 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_256 (4 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_1024 (5 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_2048 (6 << EMC_RTCSR_CKS_BIT) #define EMC_RTCSR_CKS_4096 (7 << EMC_RTCSR_CKS_BIT) // SDRAM Bank Address Configuration Register #define EMC_DMAR_BASE_BIT 8 #define EMC_DMAR_BASE_MASK (0xff << EMC_DMAR_BASE_BIT) #define EMC_DMAR_MASK_BIT 0 #define EMC_DMAR_MASK_MASK (0xff << EMC_DMAR_MASK_BIT) // Mode Register of SDRAM bank 0 #define EMC_SDMR_BM (1 << 9) // Write Burst Mode #define EMC_SDMR_OM_BIT 7 // Operating Mode #define EMC_SDMR_OM_MASK (3 << EMC_SDMR_OM_BIT) #define EMC_SDMR_OM_NORMAL (0 << EMC_SDMR_OM_BIT) #define EMC_SDMR_CAS_BIT 4 // CAS Latency #define EMC_SDMR_CAS_MASK (7 << EMC_SDMR_CAS_BIT) #define EMC_SDMR_CAS_1 (1 << EMC_SDMR_CAS_BIT) #define EMC_SDMR_CAS_2 (2 << EMC_SDMR_CAS_BIT) #define EMC_SDMR_CAS_3 (3 << EMC_SDMR_CAS_BIT) #define EMC_SDMR_BT_BIT 3 // Burst Type #define EMC_SDMR_BT_MASK (1 << EMC_SDMR_BT_BIT) #define EMC_SDMR_BT_SEQ (0 << EMC_SDMR_BT_BIT) // Sequential #define EMC_SDMR_BT_INT (1 << EMC_SDMR_BT_BIT) // Interleave #define EMC_SDMR_BL_BIT 0 // Burst Length #define EMC_SDMR_BL_MASK (7 << EMC_SDMR_BL_BIT) #define EMC_SDMR_BL_1 (0 << EMC_SDMR_BL_BIT) #define EMC_SDMR_BL_2 (1 << EMC_SDMR_BL_BIT) #define EMC_SDMR_BL_4 (2 << EMC_SDMR_BL_BIT) #define EMC_SDMR_BL_8 (3 << EMC_SDMR_BL_BIT) #define EMC_SDMR_CAS2_16BIT (EMC_SDMR_CAS_2 | EMC_SDMR_BT_SEQ | EMC_SDMR_BL_2) #define EMC_SDMR_CAS2_32BIT (EMC_SDMR_CAS_2 | EMC_SDMR_BT_SEQ | EMC_SDMR_BL_4) #define EMC_SDMR_CAS3_16BIT (EMC_SDMR_CAS_3 | EMC_SDMR_BT_SEQ | EMC_SDMR_BL_2) #define EMC_SDMR_CAS3_32BIT (EMC_SDMR_CAS_3 | EMC_SDMR_BT_SEQ | EMC_SDMR_BL_4) //************************************************************************ // CIM //************************************************************************ #define CIM_CFG REG32 (CIM_BASE + 0x0000) #define CIM_CTRL REG32 (CIM_BASE + 0x0004) #define CIM_STATE REG32 (CIM_BASE + 0x0008) #define CIM_IID REG32 (CIM_BASE + 0x000C) #define CIM_RXFIFO REG32 (CIM_BASE + 0x0010) #define CIM_DA REG32 (CIM_BASE + 0x0020) #define CIM_FA REG32 (CIM_BASE + 0x0024) #define CIM_FID REG32 (CIM_BASE + 0x0028) #define CIM_CMD REG32 (CIM_BASE + 0x002C) // CIM Configuration Register (CIM_CFG) #define CIM_CFG_INV_DAT (1 << 15) #define CIM_CFG_VSP (1 << 14) #define CIM_CFG_HSP (1 << 13) #define CIM_CFG_PCP (1 << 12) #define CIM_CFG_DUMMY_ZERO (1 << 9) #define CIM_CFG_EXT_VSYNC (1 << 8) #define CIM_CFG_PACK_BIT 4 #define CIM_CFG_PACK_MASK (0x7 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_0 (0 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_1 (1 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_2 (2 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_3 (3 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_4 (4 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_5 (5 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_6 (6 << CIM_CFG_PACK_BIT) #define CIM_CFG_PACK_7 (7 << CIM_CFG_PACK_BIT) #define CIM_CFG_DSM_BIT 0 #define CIM_CFG_DSM_MASK (0x3 << CIM_CFG_DSM_BIT) #define CIM_CFG_DSM_CPM (0 << CIM_CFG_DSM_BIT) // CCIR656 Progressive Mode #define CIM_CFG_DSM_CIM (1 << CIM_CFG_DSM_BIT) // CCIR656 Interlace Mode #define CIM_CFG_DSM_GCM (2 << CIM_CFG_DSM_BIT) // Gated Clock Mode #define CIM_CFG_DSM_NGCM (3 << CIM_CFG_DSM_BIT) // Non-Gated Clock Mode // CIM Control Register (CIM_CTRL) #define CIM_CTRL_MCLKDIV_BIT 24 #define CIM_CTRL_MCLKDIV_MASK (0xff << CIM_CTRL_MCLKDIV_BIT) #define CIM_CTRL_FRC_BIT 16 #define CIM_CTRL_FRC_MASK (0xf << CIM_CTRL_FRC_BIT) #define CIM_CTRL_FRC_1 (0x0 << CIM_CTRL_FRC_BIT) // Sample every frame #define CIM_CTRL_FRC_2 (0x1 << CIM_CTRL_FRC_BIT) // Sample 1/2 frame #define CIM_CTRL_FRC_3 (0x2 << CIM_CTRL_FRC_BIT) // Sample 1/3 frame #define CIM_CTRL_FRC_4 (0x3 << CIM_CTRL_FRC_BIT) // Sample 1/4 frame #define CIM_CTRL_FRC_5 (0x4 << CIM_CTRL_FRC_BIT) // Sample 1/5 frame #define CIM_CTRL_FRC_6 (0x5 << CIM_CTRL_FRC_BIT) // Sample 1/6 frame #define CIM_CTRL_FRC_7 (0x6 << CIM_CTRL_FRC_BIT) // Sample 1/7 frame #define CIM_CTRL_FRC_8 (0x7 << CIM_CTRL_FRC_BIT) // Sample 1/8 frame #define CIM_CTRL_FRC_9 (0x8 << CIM_CTRL_FRC_BIT) // Sample 1/9 frame #define CIM_CTRL_FRC_10 (0x9 << CIM_CTRL_FRC_BIT) // Sample 1/10 frame #define CIM_CTRL_FRC_11 (0xA << CIM_CTRL_FRC_BIT) // Sample 1/11 frame #define CIM_CTRL_FRC_12 (0xB << CIM_CTRL_FRC_BIT) // Sample 1/12 frame #define CIM_CTRL_FRC_13 (0xC << CIM_CTRL_FRC_BIT) // Sample 1/13 frame #define CIM_CTRL_FRC_14 (0xD << CIM_CTRL_FRC_BIT) // Sample 1/14 frame #define CIM_CTRL_FRC_15 (0xE << CIM_CTRL_FRC_BIT) // Sample 1/15 frame #define CIM_CTRL_FRC_16 (0xF << CIM_CTRL_FRC_BIT) // Sample 1/16 frame #define CIM_CTRL_VDDM (1 << 13) #define CIM_CTRL_DMA_SOFM (1 << 12) #define CIM_CTRL_DMA_EOFM (1 << 11) #define CIM_CTRL_DMA_STOPM (1 << 10) #define CIM_CTRL_RXF_TRIGM (1 << 9) #define CIM_CTRL_RXF_OFM (1 << 8) #define CIM_CTRL_RXF_TRIG_BIT 4 #define CIM_CTRL_RXF_TRIG_MASK (0x7 << CIM_CTRL_RXF_TRIG_BIT) #define CIM_CTRL_RXF_TRIG_4 (0 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 4 #define CIM_CTRL_RXF_TRIG_8 (1 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 8 #define CIM_CTRL_RXF_TRIG_12 (2 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 12 #define CIM_CTRL_RXF_TRIG_16 (3 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 16 #define CIM_CTRL_RXF_TRIG_20 (4 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 20 #define CIM_CTRL_RXF_TRIG_24 (5 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 24 #define CIM_CTRL_RXF_TRIG_28 (6 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 28 #define CIM_CTRL_RXF_TRIG_32 (7 << CIM_CTRL_RXF_TRIG_BIT) // RXFIFO Trigger Value is 32 #define CIM_CTRL_DMA_EN (1 << 2) #define CIM_CTRL_RXF_RST (1 << 1) #define CIM_CTRL_ENA (1 << 0) // CIM State Register (CIM_STATE) #define CIM_STATE_DMA_SOF (1 << 6) #define CIM_STATE_DMA_EOF (1 << 5) #define CIM_STATE_DMA_STOP (1 << 4) #define CIM_STATE_RXF_OF (1 << 3) #define CIM_STATE_RXF_TRIG (1 << 2) #define CIM_STATE_RXF_EMPTY (1 << 1) #define CIM_STATE_VDD (1 << 0) // CIM DMA Command Register (CIM_CMD) #define CIM_CMD_SOFINT (1 << 31) #define CIM_CMD_EOFINT (1 << 30) #define CIM_CMD_STOP (1 << 28) #define CIM_CMD_LEN_BIT 0 #define CIM_CMD_LEN_MASK (0xffffff << CIM_CMD_LEN_BIT) //************************************************************************ // SADC (Smart A/D Controller) //************************************************************************ #define SADC_ENA REG8 (SADC_BASE + 0x00) // ADC Enable Register #define SADC_CFG REG32 (SADC_BASE + 0x04) // ADC Configure Register #define SADC_CTRL REG8 (SADC_BASE + 0x08) // ADC Control Register #define SADC_STATE REG8 (SADC_BASE + 0x0C) // ADC Status Register*/ #define SADC_SAMETIME REG16 (SADC_BASE + 0x10) // ADC Same Point Time Register #define SADC_WAITTIME REG16 (SADC_BASE + 0x14) // ADC Wait Time Register #define SADC_TSDAT REG32 (SADC_BASE + 0x18) // ADC Touch Screen Data Register #define SADC_BATDAT REG16 (SADC_BASE + 0x1C) // ADC PBAT Data Register #define SADC_SADDAT REG16 (SADC_BASE + 0x20) // ADC SADCIN Data Register // ADC Enable Register #define SADC_ENA_ADEN (1 << 7) // Touch Screen Enable #define SADC_ENA_TSEN (1 << 2) // Touch Screen Enable #define SADC_ENA_PBATEN (1 << 1) // PBAT Enable #define SADC_ENA_SADCINEN (1 << 0) // SADCIN Enable // ADC Configure Register #define SADC_CFG_EXIN (1 << 30) #define SADC_CFG_CLKOUT_NUM_BIT 16 #define SADC_CFG_CLKOUT_NUM_MASK (0x7 << SADC_CFG_CLKOUT_NUM_BIT) #define SADC_CFG_TS_DMA (1 << 15) // Touch Screen DMA Enable #define SADC_CFG_XYZ_BIT 13 // XYZ selection #define SADC_CFG_XYZ_MASK (0x3 << SADC_CFG_XYZ_BIT) #define SADC_CFG_XY (0 << SADC_CFG_XYZ_BIT) #define SADC_CFG_XYZ (1 << SADC_CFG_XYZ_BIT) #define SADC_CFG_XYZ1Z2 (2 << SADC_CFG_XYZ_BIT) #define SADC_CFG_SNUM_BIT 10 // Sample Number #define SADC_CFG_SNUM_MASK (0x7 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_1 (0x0 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_2 (0x1 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_3 (0x2 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_4 (0x3 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_5 (0x4 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_6 (0x5 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_8 (0x6 << SADC_CFG_SNUM_BIT) #define SADC_CFG_SNUM_9 (0x7 << SADC_CFG_SNUM_BIT) #define SADC_CFG_CLKDIV_BIT 5 // AD Converter frequency clock divider #define SADC_CFG_CLKDIV_MASK (0x1f << SADC_CFG_CLKDIV_BIT) #define SADC_CFG_PBAT_HIGH (0 << 4) // PBAT >= 2.5V #define SADC_CFG_PBAT_LOW (1 << 4) // PBAT < 2.5V #define SADC_CFG_CMD_BIT 0 // ADC Command #define SADC_CFG_CMD_MASK (0xf << SADC_CFG_CMD_BIT) #define SADC_CFG_CMD_X_SE (0x0 << SADC_CFG_CMD_BIT) // X Single-End #define SADC_CFG_CMD_Y_SE (0x1 << SADC_CFG_CMD_BIT) // Y Single-End #define SADC_CFG_CMD_X_DIFF (0x2 << SADC_CFG_CMD_BIT) // X Differential #define SADC_CFG_CMD_Y_DIFF (0x3 << SADC_CFG_CMD_BIT) // Y Differential #define SADC_CFG_CMD_Z1_DIFF (0x4 << SADC_CFG_CMD_BIT) // Z1 Differential #define SADC_CFG_CMD_Z2_DIFF (0x5 << SADC_CFG_CMD_BIT) // Z2 Differential #define SADC_CFG_CMD_Z3_DIFF (0x6 << SADC_CFG_CMD_BIT) // Z3 Differential #define SADC_CFG_CMD_Z4_DIFF (0x7 << SADC_CFG_CMD_BIT) // Z4 Differential #define SADC_CFG_CMD_TP_SE (0x8 << SADC_CFG_CMD_BIT) // Touch Pressure #define SADC_CFG_CMD_PBATH_SE (0x9 << SADC_CFG_CMD_BIT) // PBAT >= 2.5V #define SADC_CFG_CMD_PBATL_SE (0xa << SADC_CFG_CMD_BIT) // PBAT < 2.5V #define SADC_CFG_CMD_SADCIN_SE (0xb << SADC_CFG_CMD_BIT) // Measure SADCIN #define SADC_CFG_CMD_INT_PEN (0xc << SADC_CFG_CMD_BIT) // INT_PEN Enable // ADC Control Register #define SADC_CTRL_PENDM (1 << 4) // Pen Down Interrupt Mask #define SADC_CTRL_PENUM (1 << 3) // Pen Up Interrupt Mask #define SADC_CTRL_TSRDYM (1 << 2) // Touch Screen Data Ready Interrupt Mask #define SADC_CTRL_PBATRDYM (1 << 1) // PBAT Data Ready Interrupt Mask #define SADC_CTRL_SRDYM (1 << 0) // SADCIN Data Ready Interrupt Mask // ADC Status Register #define SADC_STATE_TSBUSY (1 << 7) // TS A/D is working #define SADC_STATE_PBATBUSY (1 << 6) // PBAT A/D is working #define SADC_STATE_SBUSY (1 << 5) // SADCIN A/D is working #define SADC_STATE_PEND (1 << 4) // Pen Down Interrupt Flag #define SADC_STATE_PENU (1 << 3) // Pen Up Interrupt Flag #define SADC_STATE_TSRDY (1 << 2) // Touch Screen Data Ready Interrupt Flag #define SADC_STATE_PBATRDY (1 << 1) // PBAT Data Ready Interrupt Flag #define SADC_STATE_SRDY (1 << 0) // SADCIN Data Ready Interrupt Flag // ADC Touch Screen Data Register #define SADC_TSDAT_DATA0_BIT 0 #define SADC_TSDAT_DATA0_MASK (0xfff << SADC_TSDAT_DATA0_BIT) #define SADC_TSDAT_TYPE0 (1 << 15) #define SADC_TSDAT_DATA1_BIT 16 #define SADC_TSDAT_DATA1_MASK (0xfff << SADC_TSDAT_DATA1_BIT) #define SADC_TSDAT_TYPE1 (1 << 31) //************************************************************************ // SLCD (Smart LCD Controller) //************************************************************************ #define SLCD_CFG REG32 (SLCD_BASE + 0xA0) // SLCD Configure Register #define SLCD_CTRL REG8 (SLCD_BASE + 0xA4) // SLCD Control Register #define SLCD_STATE REG8 (SLCD_BASE + 0xA8) // SLCD Status Register #define SLCD_DATA REG32 (SLCD_BASE + 0xAC) // SLCD Data Register #define SLCD_FIFO REG32 (SLCD_BASE + 0xB0) // SLCD FIFO Register // SLCD Configure Register #define SLCD_CFG_BURST_BIT 14 #define SLCD_CFG_BURST_MASK (0x3 << SLCD_CFG_BURST_BIT) #define SLCD_CFG_BURST_4_WORD (0 << SLCD_CFG_BURST_BIT) #define SLCD_CFG_BURST_8_WORD (1 << SLCD_CFG_BURST_BIT) #define SLCD_CFG_DWIDTH_BIT 10 #define SLCD_CFG_DWIDTH_MASK (0x7 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_DWIDTH_18 (0 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_DWIDTH_16 (1 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_DWIDTH_8_x3 (2 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_DWIDTH_8_x2 (3 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_DWIDTH_9_x2 (4 << SLCD_CFG_DWIDTH_BIT) #define SLCD_CFG_CWIDTH_16BIT (0 << 8) #define SLCD_CFG_CWIDTH_8BIT (1 << 8) #define SLCD_CFG_CS_ACTIVE_LOW (0 << 4) #define SLCD_CFG_CS_ACTIVE_HIGH (1 << 4) #define SLCD_CFG_RS_CMD_LOW (0 << 3) #define SLCD_CFG_RS_CMD_HIGH (1 << 3) #define SLCD_CFG_CLK_ACTIVE_FALLING (0 << 1) #define SLCD_CFG_CLK_ACTIVE_RISING (1 << 1) #define SLCD_CFG_TYPE_PARALLEL (0 << 0) #define SLCD_CFG_TYPE_SERIAL (1 << 0) // SLCD Control Register #define SLCD_CTRL_DMA_EN (1 << 0) // SLCD Status Register #define SLCD_STATE_BUSY (1 << 0) // SLCD Data Register #define SLCD_DATA_RS_DATA (0 << 31) #define SLCD_DATA_RS_COMMAND (1 << 31) // SLCD FIFO Register #define SLCD_FIFO_RS_DATA (0 << 31) #define SLCD_FIFO_RS_COMMAND (1 << 31) //************************************************************************ // LCD (LCD Controller) //************************************************************************ #define LCD_CFG REG32 (LCD_BASE + 0x00) // LCD Configure Register #define LCD_VSYNC REG32 (LCD_BASE + 0x04) // Vertical Synchronize Register #define LCD_HSYNC REG32 (LCD_BASE + 0x08) // Horizontal Synchronize Register #define LCD_VAT REG32 (LCD_BASE + 0x0c) // Virtual Area Setting Register #define LCD_DAH REG32 (LCD_BASE + 0x10) // Display Area Horizontal Start/End Point #define LCD_DAV REG32 (LCD_BASE + 0x14) // Display Area Vertical Start/End Point #define LCD_PS REG32 (LCD_BASE + 0x18) // PS Signal Setting #define LCD_CLS REG32 (LCD_BASE + 0x1c) // CLS Signal Setting #define LCD_SPL REG32 (LCD_BASE + 0x20) // SPL Signal Setting #define LCD_REV REG32 (LCD_BASE + 0x24) // REV Signal Setting #define LCD_CTRL REG32 (LCD_BASE + 0x30) // LCD Control Register #define LCD_STATE REG32 (LCD_BASE + 0x34) // LCD Status Register #define LCD_IID REG32 (LCD_BASE + 0x38) // Interrupt ID Register #define LCD_DA0 REG32 (LCD_BASE + 0x40) // Descriptor Address Register 0 #define LCD_SA0 REG32 (LCD_BASE + 0x44) // Source Address Register 0 #define LCD_FID0 REG32 (LCD_BASE + 0x48) // Frame ID Register 0 #define LCD_CMD0 REG32 (LCD_BASE + 0x4c) // DMA Command Register 0 #define LCD_DA1 REG32 (LCD_BASE + 0x50) // Descriptor Address Register 1 #define LCD_SA1 REG32 (LCD_BASE + 0x54) // Source Address Register 1 #define LCD_FID1 REG32 (LCD_BASE + 0x58) // Frame ID Register 1 #define LCD_CMD1 REG32 (LCD_BASE + 0x5c) // DMA Command Register 1 // LCD Configure Register #define LCD_CFG_LCDPIN_BIT 31 // LCD pins selection #define LCD_CFG_LCDPIN_MASK (0x1 << LCD_CFG_LCDPIN_BIT) #define LCD_CFG_LCDPIN_LCD (0x0 << LCD_CFG_LCDPIN_BIT) #define LCD_CFG_LCDPIN_SLCD (0x1 << LCD_CFG_LCDPIN_BIT) #define LCD_CFG_PSM (1 << 23) // PS signal mode #define LCD_CFG_CLSM (1 << 22) // CLS signal mode #define LCD_CFG_SPLM (1 << 21) // SPL signal mode #define LCD_CFG_REVM (1 << 20) // REV signal mode #define LCD_CFG_HSYNM (1 << 19) // HSYNC signal mode #define LCD_CFG_PCLKM (1 << 18) // PCLK signal mode #define LCD_CFG_INVDAT (1 << 17) // Inverse output data #define LCD_CFG_SYNDIR_IN (1 << 16) // VSYNC&HSYNC direction #define LCD_CFG_PSP (1 << 15) // PS pin reset state #define LCD_CFG_CLSP (1 << 14) // CLS pin reset state #define LCD_CFG_SPLP (1 << 13) // SPL pin reset state #define LCD_CFG_REVP (1 << 12) // REV pin reset state #define LCD_CFG_HSP (1 << 11) // HSYNC pority:0-active high,1-active low #define LCD_CFG_PCP (1 << 10) // PCLK pority:0-rising,1-falling #define LCD_CFG_DEP (1 << 9) // DE pority:0-active high,1-active low #define LCD_CFG_VSP (1 << 8) // VSYNC pority:0-rising,1-falling #define LCD_CFG_PDW_BIT 4 // STN pins utilization #define LCD_CFG_PDW_MASK (0x3 << LCD_DEV_PDW_BIT) #define LCD_CFG_PDW_1 (0 << LCD_CFG_PDW_BIT) // LCD_D[0] #define LCD_CFG_PDW_2 (1 << LCD_CFG_PDW_BIT) // LCD_D[0:1] #define LCD_CFG_PDW_4 (2 << LCD_CFG_PDW_BIT) // LCD_D[0:3]/LCD_D[8:11] #define LCD_CFG_PDW_8 (3 << LCD_CFG_PDW_BIT) // LCD_D[0:7]/LCD_D[8:15] #define LCD_CFG_MODE_BIT 0 // Display Device Mode Select #define LCD_CFG_MODE_MASK (0x0f << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_GENERIC_TFT (0 << LCD_CFG_MODE_BIT) // 16,18 bit TFT #define LCD_CFG_MODE_SPECIAL_TFT_1 (1 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SPECIAL_TFT_2 (2 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SPECIAL_TFT_3 (3 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_NONINTER_CCIR656 (4 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_INTER_CCIR656 (5 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SINGLE_CSTN (8 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SINGLE_MSTN (9 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_DUAL_CSTN (10 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_DUAL_MSTN (11 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SERIAL_TFT (12 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_GENERIC_18BIT_TFT (13 << LCD_CFG_MODE_BIT) // JZ47XX defines #define LCD_CFG_MODE_SHARP_HR (1 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_CASIO_TFT (2 << LCD_CFG_MODE_BIT) #define LCD_CFG_MODE_SAMSUNG_ALPHA (3 << LCD_CFG_MODE_BIT) // Vertical Synchronize Register #define LCD_VSYNC_VPS_BIT 16 // VSYNC pulse start in line clock, fixed to 0 #define LCD_VSYNC_VPS_MASK (0xffff << LCD_VSYNC_VPS_BIT) #define LCD_VSYNC_VPE_BIT 0 // VSYNC pulse end in line clock #define LCD_VSYNC_VPE_MASK (0xffff << LCD_VSYNC_VPS_BIT) // Horizontal Synchronize Register #define LCD_HSYNC_HPS_BIT 16 // HSYNC pulse start position in dot clock #define LCD_HSYNC_HPS_MASK (0xffff << LCD_HSYNC_HPS_BIT) #define LCD_HSYNC_HPE_BIT 0 // HSYNC pulse end position in dot clock #define LCD_HSYNC_HPE_MASK (0xffff << LCD_HSYNC_HPE_BIT) // Virtual Area Setting Register #define LCD_VAT_HT_BIT 16 // Horizontal Total size in dot clock #define LCD_VAT_HT_MASK (0xffff << LCD_VAT_HT_BIT) #define LCD_VAT_VT_BIT 0 // Vertical Total size in dot clock #define LCD_VAT_VT_MASK (0xffff << LCD_VAT_VT_BIT) // Display Area Horizontal Start/End Point Register #define LCD_DAH_HDS_BIT 16 // Horizontal display area start in dot clock #define LCD_DAH_HDS_MASK (0xffff << LCD_DAH_HDS_BIT) #define LCD_DAH_HDE_BIT 0 // Horizontal display area end in dot clock #define LCD_DAH_HDE_MASK (0xffff << LCD_DAH_HDE_BIT) // Display Area Vertical Start/End Point Register #define LCD_DAV_VDS_BIT 16 // Vertical display area start in line clock #define LCD_DAV_VDS_MASK (0xffff << LCD_DAV_VDS_BIT) #define LCD_DAV_VDE_BIT 0 // Vertical display area end in line clock #define LCD_DAV_VDE_MASK (0xffff << LCD_DAV_VDE_BIT) // PS Signal Setting #define LCD_PS_PSS_BIT 16 // PS signal start position in dot clock #define LCD_PS_PSS_MASK (0xffff << LCD_PS_PSS_BIT) #define LCD_PS_PSE_BIT 0 // PS signal end position in dot clock #define LCD_PS_PSE_MASK (0xffff << LCD_PS_PSE_BIT) // CLS Signal Setting #define LCD_CLS_CLSS_BIT 16 // CLS signal start position in dot clock #define LCD_CLS_CLSS_MASK (0xffff << LCD_CLS_CLSS_BIT) #define LCD_CLS_CLSE_BIT 0 // CLS signal end position in dot clock #define LCD_CLS_CLSE_MASK (0xffff << LCD_CLS_CLSE_BIT) // SPL Signal Setting #define LCD_SPL_SPLS_BIT 16 // SPL signal start position in dot clock #define LCD_SPL_SPLS_MASK (0xffff << LCD_SPL_SPLS_BIT) #define LCD_SPL_SPLE_BIT 0 // SPL signal end position in dot clock #define LCD_SPL_SPLE_MASK (0xffff << LCD_SPL_SPLE_BIT) // REV Signal Setting #define LCD_REV_REVS_BIT 16 // REV signal start position in dot clock #define LCD_REV_REVS_MASK (0xffff << LCD_REV_REVS_BIT) // LCD Control Register #define LCD_CTRL_BST_BIT 28 // Burst Length Selection #define LCD_CTRL_BST_MASK (0x03 << LCD_CTRL_BST_BIT) #define LCD_CTRL_BST_4 (0 << LCD_CTRL_BST_BIT) // 4-word #define LCD_CTRL_BST_8 (1 << LCD_CTRL_BST_BIT) // 8-word #define LCD_CTRL_BST_16 (2 << LCD_CTRL_BST_BIT) // 16-word #define LCD_CTRL_RGB565 (0 << 27) // RGB565 mode #define LCD_CTRL_RGB555 (1 << 27) // RGB555 mode #define LCD_CTRL_OFUP (1 << 26) // Output FIFO underrun protection enable #define LCD_CTRL_FRC_BIT 24 // STN FRC Algorithm Selection #define LCD_CTRL_FRC_MASK (0x03 << LCD_CTRL_FRC_BIT) #define LCD_CTRL_FRC_16 (0 << LCD_CTRL_FRC_BIT) // 16 grayscale #define LCD_CTRL_FRC_4 (1 << LCD_CTRL_FRC_BIT) // 4 grayscale #define LCD_CTRL_FRC_2 (2 << LCD_CTRL_FRC_BIT) // 2 grayscale #define LCD_CTRL_PDD_BIT 16 // Load Palette Delay Counter #define LCD_CTRL_PDD_MASK (0xff << LCD_CTRL_PDD_BIT) #define LCD_CTRL_EOFM (1 << 13) // EOF interrupt mask #define LCD_CTRL_SOFM (1 << 12) // SOF interrupt mask #define LCD_CTRL_OFUM (1 << 11) // Output FIFO underrun interrupt mask #define LCD_CTRL_IFUM0 (1 << 10) // Input FIFO 0 underrun interrupt mask #define LCD_CTRL_IFUM1 (1 << 9) // Input FIFO 1 underrun interrupt mask #define LCD_CTRL_LDDM (1 << 8) // LCD disable done interrupt mask #define LCD_CTRL_QDM (1 << 7) // LCD quick disable done interrupt mask #define LCD_CTRL_BEDN (1 << 6) // Endian selection #define LCD_CTRL_PEDN (1 << 5) // Endian in byte:0-msb first, 1-lsb first #define LCD_CTRL_DIS (1 << 4) // Disable indicate bit #define LCD_CTRL_ENA (1 << 3) // LCD enable bit #define LCD_CTRL_BPP_BIT 0 // Bits Per Pixel #define LCD_CTRL_BPP_MASK (0x07 << LCD_CTRL_BPP_BIT) #define LCD_CTRL_BPP_1 (0 << LCD_CTRL_BPP_BIT) // 1 bpp #define LCD_CTRL_BPP_2 (1 << LCD_CTRL_BPP_BIT) // 2 bpp #define LCD_CTRL_BPP_4 (2 << LCD_CTRL_BPP_BIT) // 4 bpp #define LCD_CTRL_BPP_8 (3 << LCD_CTRL_BPP_BIT) // 8 bpp #define LCD_CTRL_BPP_16 (4 << LCD_CTRL_BPP_BIT) // 15/16 bpp #define LCD_CTRL_BPP_18_24 (5 << LCD_CTRL_BPP_BIT) // 18/24/32 bpp // LCD Status Register #define LCD_STATE_QD (1 << 7) // Quick Disable Done #define LCD_STATE_EOF (1 << 5) // EOF Flag #define LCD_STATE_SOF (1 << 4) // SOF Flag #define LCD_STATE_OFU (1 << 3) // Output FIFO Underrun #define LCD_STATE_IFU0 (1 << 2) // Input FIFO 0 Underrun #define LCD_STATE_IFU1 (1 << 1) // Input FIFO 1 Underrun #define LCD_STATE_LDD (1 << 0) // LCD Disabled // DMA Command Register #define LCD_CMD_SOFINT (1 << 31) #define LCD_CMD_EOFINT (1 << 30) #define LCD_CMD_PAL (1 << 28) #define LCD_CMD_LEN_BIT 0 #define LCD_CMD_LEN_MASK (0xffffff << LCD_CMD_LEN_BIT) //************************************************************************ // USB Device //************************************************************************ #define UDC_FADDR REG8 (UDC_BASE + 0x00) // Function Address 8-bit #define UDC_POWER REG8 (UDC_BASE + 0x01) // Power Managemetn 8-bit #define UDC_INTRIN REG16 (UDC_BASE + 0x02) // Interrupt IN 16-bit #define UDC_INTROUT REG16 (UDC_BASE + 0x04) // Interrupt OUT 16-bit #define UDC_INTRINE REG16 (UDC_BASE + 0x06) // Intr IN enable 16-bit #define UDC_INTROUTE REG16 (UDC_BASE + 0x08) // Intr OUT enable 16-bit #define UDC_INTRUSB REG8 (UDC_BASE + 0x0a) // Interrupt USB 8-bit #define UDC_INTRUSBE REG8 (UDC_BASE + 0x0b) // Interrupt USB Enable 8-bit #define UDC_FRAME REG16 (UDC_BASE + 0x0c) // Frame number 16-bit #define UDC_INDEX REG8 (UDC_BASE + 0x0e) // Index register 8-bit #define UDC_TESTMODE REG8 (UDC_BASE + 0x0f) // USB test mode 8-bit #define UDC_CSR0 REG8 (UDC_BASE + 0x12) // EP0 CSR 8-bit #define UDC_INMAXP REG16 (UDC_BASE + 0x10) // EP1-2 IN Max Pkt Size 16-bit #define UDC_INCSR REG16 (UDC_BASE + 0x12) // EP1-2 IN CSR LSB 8/16bit #define UDC_INCSRH REG8 (UDC_BASE + 0x13) // EP1-2 IN CSR MSB 8-bit #define UDC_OUTMAXP REG16 (UDC_BASE + 0x14) // EP1 OUT Max Pkt Size 16-bit #define UDC_OUTCSR REG16 (UDC_BASE + 0x16) // EP1 OUT CSR LSB 8/16bit #define UDC_OUTCSRH REG8 (UDC_BASE + 0x17) // EP1 OUT CSR MSB 8-bit #define UDC_OUTCOUNT REG16 (UDC_BASE + 0x18) // bytes in EP0/1 OUT FIFO 16-bit #define UDC_FIFO(ep) REG32 (UDC_BASE + 0x20 + 4 * (ep)) #define UDC_FIFO8(ep) REG8 (UDC_BASE + 0x20 + 4 * (ep)) #define UDC_EPINFO REG32 (UDC_BASE + 0x78) // Endpoint information #define UDC_RAMINFO REG32 (UDC_BASE + 0x79) // RAM information #define UDC_INTR REG32 (UDC_BASE + 0x200) // DMA pending interrupts #define UDC_CNTL1 REG32 (UDC_BASE + 0x204) // DMA channel 1 control #define UDC_ADDR1 REG32 (UDC_BASE + 0x208) // DMA channel 1 AHB memory addr #define UDC_COUNT1 REG32 (UDC_BASE + 0x20c) // DMA channel 1 byte count #define UDC_CNTL2 REG32 (UDC_BASE + 0x214) // DMA channel 2 control #define UDC_ADDR2 REG32 (UDC_BASE + 0x218) // DMA channel 2 AHB memory addr #define UDC_COUNT2 REG32 (UDC_BASE + 0x21c) // DMA channel 2 byte count // Power register bit masks #define UDC_POWER_SUSPENDM 0x01 #define UDC_POWER_RESUME 0x04 #define UDC_POWER_HSMODE 0x10 #define UDC_POWER_HSENAB 0x20 #define UDC_POWER_SOFTCONN 0x40 // Interrupt register bit masks #define UDC_INTR_SUSPEND 0x01 #define UDC_INTR_RESUME 0x02 #define UDC_INTR_RESET 0x04 #define UDC_INTR_EP0 0x0001 #define UDC_INTR_INEP1 0x0002 #define UDC_INTR_INEP2 0x0004 #define UDC_INTR_OUTEP1 0x0002 // CSR0 bit masks #define UDC_CSR0_OUTPKTRDY 0x01 #define UDC_CSR0_INPKTRDY 0x02 #define UDC_CSR0_SENTSTALL 0x04 #define UDC_CSR0_DATAEND 0x08 #define UDC_CSR0_SETUPEND 0x10 #define UDC_CSR0_SENDSTALL 0x20 #define UDC_CSR0_SVDOUTPKTRDY 0x40 #define UDC_CSR0_SVDSETUPEND 0x80 // Endpoint CSR register bits #define UDC_INCSRH_AUTOSET 0x80 #define UDC_INCSRH_ISO 0x40 #define UDC_INCSRH_MODE 0x20 #define UDC_INCSRH_DMAREQENAB 0x10 #define UDC_INCSRH_DMAREQMODE 0x04 #define UDC_INCSR_CDT 0x40 #define UDC_INCSR_SENTSTALL 0x20 #define UDC_INCSR_SENDSTALL 0x10 #define UDC_INCSR_FF 0x08 #define UDC_INCSR_UNDERRUN 0x04 #define UDC_INCSR_FFNOTEMPT 0x02 #define UDC_INCSR_INPKTRDY 0x01 #define UDC_OUTCSRH_AUTOCLR 0x80 #define UDC_OUTCSRH_ISO 0x40 #define UDC_OUTCSRH_DMAREQENAB 0x20 #define UDC_OUTCSRH_DNYT 0x10 #define UDC_OUTCSRH_DMAREQMODE 0x08 #define UDC_OUTCSR_CDT 0x80 #define UDC_OUTCSR_SENTSTALL 0x40 #define UDC_OUTCSR_SENDSTALL 0x20 #define UDC_OUTCSR_FF 0x10 #define UDC_OUTCSR_DATAERR 0x08 #define UDC_OUTCSR_OVERRUN 0x04 #define UDC_OUTCSR_FFFULL 0x02 #define UDC_OUTCSR_OUTPKTRDY 0x01 // Testmode register bits #define UDC_TEST_SE0NAK 0x01 #define UDC_TEST_J 0x02 #define UDC_TEST_K 0x04 #define UDC_TEST_PACKET 0x08 // DMA control bits #define UDC_CNTL_ENA 0x01 #define UDC_CNTL_DIR_IN 0x02 #define UDC_CNTL_MODE_1 0x04 #define UDC_CNTL_INTR_EN 0x08 #define UDC_CNTL_EP(n) ((n) << 4) #define UDC_CNTL_BURST_0 (0 << 9) #define UDC_CNTL_BURST_4 (1 << 9) #define UDC_CNTL_BURST_8 (2 << 9) #define UDC_CNTL_BURST_16 (3 << 9) //########################################################################## //************************************************************************** // GPIO //************************************************************************** //------------------------------------------------------ // GPIO Pins Description // // PORT 0 // // PIN/BIT N FUNC0 FUNC1 // 0 D0 - // 1 D1 - // 2 D2 - // 3 D3 - // 4 D4 - // 5 D5 - // 6 D6 - // 7 D7 - // 8 D8 - // 9 D9 - // 10 D10 - // 11 D11 - // 12 D12 - // 13 D13 - // 14 D14 - // 15 D15 - // 16 D16 - // 17 D17 - // 18 D18 - // 19 D19 - // 20 D20 - // 21 D21 - // 22 D22 - // 23 D23 - // 24 D24 - // 25 D25 - // 26 D26 - // 27 D27 - // 28 D28 - // 29 D29 - // 30 D30 - // 31 D31 - // //------------------------------------------------------ // PORT 1 // // PIN/BIT N FUNC0 FUNC1 // 0 A0 - // 1 A1 - // 2 A2 - // 3 A3 - // 4 A4 - // 5 A5 - // 6 A6 - // 7 A7 - // 8 A8 - // 9 A9 - // 10 A10 - // 11 A11 - // 12 A12 - // 13 A13 - // 14 A14 - // 15 A15/CL - // 16 A16/AL - // 17 LCD_CLS A21 // 18 LCD_SPL A22 // 19 DCS# - // 20 RAS# - // 21 CAS# - // 22 RDWE#/BUFD# - // 23 CKE - // 24 CKO - // 25 CS1# - // 26 CS2# - // 27 CS3# - // 28 CS4# - // 29 RD# - // 30 WR# - // 31 WE0# - // // Note: PIN15&16 are CL&AL when connecting to NAND flash. //------------------------------------------------------ // PORT 2 // // PIN/BIT N FUNC0 FUNC1 // 0 LCD_D0 - // 1 LCD_D1 - // 2 LCD_D2 - // 3 LCD_D3 - // 4 LCD_D4 - // 5 LCD_D5 - // 6 LCD_D6 - // 7 LCD_D7 - // 8 LCD_D8 - // 9 LCD_D9 - // 10 LCD_D10 - // 11 LCD_D11 - // 12 LCD_D12 - // 13 LCD_D13 - // 14 LCD_D14 - // 15 LCD_D15 - // 16 LCD_D16 - // 17 LCD_D17 - // 18 LCD_PCLK - // 19 LCD_HSYNC - // 20 LCD_VSYNC - // 21 LCD_DE - // 22 LCD_PS A19 // 23 LCD_REV A20 // 24 WE1# - // 25 WE2# - // 26 WE3# - // 27 WAIT# - // 28 FRE# - // 29 FWE# - // 30(NOTE:FRB#) - - // 31 - - // // NOTE(1): PIN30 is used for FRB# when connecting to NAND flash. //------------------------------------------------------ // PORT 3 // // PIN/BIT N FUNC0 FUNC1 // 0 CIM_D0 - // 1 CIM_D1 - // 2 CIM_D2 - // 3 CIM_D3 - // 4 CIM_D4 - // 5 CIM_D5 - // 6 CIM_D6 - // 7 CIM_D7 - // 8 MSC_CMD - // 9 MSC_CLK - // 10 MSC_D0 - // 11 MSC_D1 - // 12 MSC_D2 - // 13 MSC_D3 - // 14 CIM_MCLK - // 15 CIM_PCLK - // 16 CIM_VSYNC - // 17 CIM_HSYNC - // 18 SSI_CLK SCLK_RSTN // 19 SSI_CE0# BIT_CLK(AIC) // 20 SSI_DT SDATA_OUT(AIC) // 21 SSI_DR SDATA_IN(AIC) // 22 SSI_CE1#&GPC SYNC(AIC) // 23 PWM0 I2C_SDA // 24 PWM1 I2C_SCK // 25 PWM2 UART0_TxD // 26 PWM3 UART0_RxD // 27 PWM4 A17 // 28 PWM5 A18 // 29 - - // 30 PWM6 UART0_CTS/UART1_RxD // 31 PWM7 UART0_RTS/UART1_TxD // ////////////////////////////////////////////////////////// // p is the port number (0,1,2,3) // o is the pin offset (0-31) inside the port //------------------------------------------- // Function Pins Mode static void gpio_as_func0 (unsigned p, unsigned o): GPIO_PXFUNS (p) = (1 << o) GPIO_PXSELC (p) = (1 << o) static void gpio_as_func1 (unsigned p, unsigned o): GPIO_PXFUNS (p) = (1 << o) GPIO_PXSELS (p) = (1 << o) // D0 ~ D31, A0 ~ A16, DCS#, RAS#, CAS#, CKE#, RDWE#, CKO#, WE0#, WE1#, WE2#, WE3# static void gpio_as_sdram_32bit (): GPIO_PXFUNS (0) = 0xffffffff GPIO_PXSELC (0) = 0xffffffff GPIO_PXPES (0) = 0xffffffff GPIO_PXFUNS (1) = 0x81f9ffff GPIO_PXSELC (1) = 0x81f9ffff GPIO_PXPES (1) = 0x81f9ffff GPIO_PXFUNS (2) = 0x07000000 GPIO_PXSELC (2) = 0x07000000 GPIO_PXPES (2) = 0x07000000 // D0 ~ D15, A0 ~ A16, DCS#, RAS#, CAS#, CKE#, RDWE#, CKO#, WE0#, WE1# static void gpio_as_sdram_16bit(): GPIO_PXFUNS (0) = 0x5442bfaa GPIO_PXSELC (0) = 0x5442bfaa GPIO_PXPES (0) = 0x5442bfaa GPIO_PXFUNS (1) = 0x81f9ffff GPIO_PXSELC (1) = 0x81f9ffff GPIO_PXPES (1) = 0x81f9ffff GPIO_PXFUNS (2) = 0x01000000 GPIO_PXSELC (2) = 0x01000000 GPIO_PXPES (2) = 0x01000000 // CS1#, CLE, ALE, FRE#, FWE#, FRB#, RDWE#/BUFD# static void gpio_as_nand (): GPIO_PXFUNS (1) = 0x02018000 GPIO_PXSELC (1) = 0x02018000 GPIO_PXPES (1) = 0x02018000 GPIO_PXFUNS (2) = 0x30000000 GPIO_PXSELC (2) = 0x30000000 GPIO_PXPES (2) = 0x30000000 GPIO_PXFUNC (2) = 0x40000000 GPIO_PXSELC (2) = 0x40000000 GPIO_PXDIRC (2) = 0x40000000 GPIO_PXPES (2) = 0x40000000 GPIO_PXFUNS (1) = 0x00400000 GPIO_PXSELC (1) = 0x00400000 // UART0_TxD, UART_RxD0 static void gpio_as_uart0 (): GPIO_PXFUNS (3) = 0x06000000 GPIO_PXSELS (3) = 0x06000000 GPIO_PXPES (3) = 0x06000000 // UART0_CTS, UART0_RTS static void gpio_as_ctsrts (): GPIO_PXFUNS (3) = 0xc0000000 GPIO_PXSELS (3) = 0xc0000000 GPIO_PXTRGC (3) = 0xc0000000 GPIO_PXPES (3) = 0xc0000000 // UART1_TxD, UART1_RxD1 static void gpio_as_uart1(): GPIO_PXFUNS (3) = 0xc0000000 GPIO_PXSELC (3) = 0xc0000000 GPIO_PXTRGS (3) = 0xc0000000 GPIO_PXPES (3) = 0xc0000000 // LCD_D0~LCD_D15, LCD_PCLK, LCD_HSYNC, LCD_VSYNC, LCD_DE static void gpio_as_lcd_16bit (): GPIO_PXFUNS (2) = 0x003cffff GPIO_PXSELC (2) = 0x003cffff GPIO_PXPES (2) = 0x003cffff // LCD_D0~LCD_D17, LCD_PCLK, LCD_HSYNC, LCD_VSYNC, LCD_DE static void gpio_as_lcd_18bit (): GPIO_PXFUNS (2) = 0x003fffff GPIO_PXSELC (2) = 0x003fffff GPIO_PXPES (2) = 0x003fffff // LCD_PS, LCD_REV, LCD_CLS, LCD_SPL static void gpio_as_lcd_spl (): GPIO_PXFUNS (1) = 0x00060000 GPIO_PXSELC (1) = 0x00060000 GPIO_PXPES (1) = 0x00060000 GPIO_PXFUNS (2) = 0x00c00000 GPIO_PXSELC (2) = 0x00c00000 GPIO_PXPES (2) = 0x00c00000 // CIM_D0~CIM_D7, CIM_MCLK, CIM_PCLK, CIM_VSYNC, CIM_HSYNC static void gpio_as_cim (): GPIO_PXFUNS (3) = 0x0003c0ff GPIO_PXSELC (3) = 0x0003c0ff GPIO_PXPES (3) = 0x0003c0ff // SDATA_OUT, SDATA_IN, BIT_CLK, SYNC, SCLK_RESET static void gpio_as_aic (): GPIO_PXFUNS(3) = 0x007c0000 GPIO_PXSELS(3) = 0x007c0000 GPIO_PXPES(3) = 0x007c0000 // MSC_CMD, MSC_CLK, MSC_D0 ~ MSC_D3 static void gpio_as_msc (): GPIO_PXFUNS (3) = 0x00003f00 GPIO_PXSELC (3) = 0x00003f00 GPIO_PXPES (3) = 0x00003f00 // SSI_CS0, SSI_CLK, SSI_DT, SSI_DR static void gpio_as_ssi (): GPIO_PXFUNS (3) = 0x003c0000 GPIO_PXSELC (3) = 0x003c0000 GPIO_PXPES (3) = 0x003c0000 // I2C_SCK, I2C_SDA static void gpio_as_i2c (): GPIO_PXFUNS (3) = 0x01800000 GPIO_PXSELS (3) = 0x01800000 GPIO_PXPES (3) = 0x01800000 // PWM* static void gpio_as_pwm0 (): GPIO_PXFUNS (3) = 0x00800000 GPIO_PXSELC (3) = 0x00800000 GPIO_PXPES (3) = 0x00800000 static void gpio_as_pwm1 (): GPIO_PXFUNS (3) = 0x01000000 GPIO_PXSELC (3) = 0x01000000 GPIO_PXPES (3) = 0x01000000 static void gpio_as_pwm2 (): GPIO_PXFUNS (3) = 0x02000000 GPIO_PXSELC (3) = 0x02000000 GPIO_PXPES (3) = 0x02000000 static void gpio_as_pwm3 (): GPIO_PXFUNS (3) = 0x04000000 GPIO_PXSELC (3) = 0x04000000 GPIO_PXPES (3) = 0x04000000 static void gpio_as_pwm4 (): GPIO_PXFUNS (3) = 0x08000000 GPIO_PXSELC (3) = 0x08000000 GPIO_PXPES (3) = 0x08000000 static void gpio_as_pwm5 (): GPIO_PXFUNS (3) = 0x10000000 GPIO_PXSELC (3) = 0x10000000 GPIO_PXPES (3) = 0x10000000 static void gpio_as_pwm6 (): GPIO_PXFUNS (3) = 0x40000000 GPIO_PXSELC (3) = 0x40000000 GPIO_PXPES (3) = 0x40000000 static void gpio_as_pwm7 (): GPIO_PXFUNS (3) = 0x80000000 GPIO_PXSELC (3) = 0x80000000 GPIO_PXPES (3) = 0x80000000 // n = 0 ~ 7 #define gpio_as_pwm(n) (gpio_as_pwm##n ()) //------------------------------------------- // GPIO or Interrupt Mode static unsigned gpio_get_port (unsigned p): return GPIO_PXPIN (p) static unsigned gpio_get_irqs (unsigned p): return GPIO_PXFLG (p) static void gpio_as_gpio (unsigned p, unsigned pins): GPIO_PXFUNC (p) = pins static void gpio_as_output (unsigned p, unsigned pins): GPIO_PXDIRS (p) = pins static void gpio_as_input (unsigned p, unsigned pins): GPIO_PXDIRC (p) = pins // Set gpio as interrupt. It must already be set as gpio. It must be unmasked before it will trigger. static void gpio_as_interrupt (unsigned p, unsigned pins, bool high, bool level): GPIO_PXIMS (p) = pins if level: GPIO_PXTRGC (p) = pins else: GPIO_PXTRGS (p) = pins GPIO_PXSELS (p) = pins if high: GPIO_PXDIRS (p) = pins else: GPIO_PXDIRC (p) = pins GPIO_PXFLGC (p) = pins static void gpio_set (unsigned p, unsigned pins): GPIO_PXDATS (p) = pins static void gpio_clear (unsigned p, unsigned pins): GPIO_PXDATC (p) = pins static void gpio_mask_irq (unsigned p, unsigned pins): GPIO_PXIMS (p) = pins static void gpio_unmask_irq (unsigned p, unsigned pins): GPIO_PXIMC (p) = pins static void gpio_ack_irq (unsigned p, unsigned pins): GPIO_PXFLGC (p) = pins static void gpio_enable_pull (unsigned p, unsigned pins): GPIO_PXPEC (p) = pins static void gpio_disable_pull (unsigned p, unsigned pins): GPIO_PXPES (p) = pins //************************************************************************** // CPM //************************************************************************** static void pll_init (): // The cpu clock frequency //unsigned const cpu_clock = 336000000 //unsigned const pixclock = 25846153 unsigned const cpu_clock = 200000000 unsigned const pixclock = 13500000 // Configure the pll frequency to cpu_clock. CPM_CPPCR = ((cpu_clock * 2 / JZ_EXTAL - 2) << CPM_CPPCR_PLLM_BIT) | (0 << CPM_CPPCR_PLLN_BIT) | (0 << CPM_CPPCR_PLLOD_BIT) | (0x20 << CPM_CPPCR_PLLST_BIT) | CPM_CPPCR_PLLEN // Set up dividers; see documentation for the meaning of all the values. // USB clock seems to work when bypassing the pll. (even though it must be 48 MHz according to the datasheet.) CPM_CPCCR = CPM_CPCCR_CLKOEN | (0 << CPM_CPCCR_CDIV_BIT) | (2 << CPM_CPCCR_HDIV_BIT) | (2 << CPM_CPCCR_PDIV_BIT) | (2 << CPM_CPCCR_MDIV_BIT) | (3 << CPM_CPCCR_LDIV_BIT) | CPM_CPCCR_CE | CPM_CPCCR_PCS CPM_LPCDR = (cpu_clock / pixclock) - 1 static unsigned cpm_get_pllm (): return (CPM_CPPCR & CPM_CPPCR_PLLM_MASK) >> CPM_CPPCR_PLLM_BIT static unsigned cpm_get_plln (): return (CPM_CPPCR & CPM_CPPCR_PLLN_MASK) >> CPM_CPPCR_PLLN_BIT static unsigned cpm_get_pllod (): return (CPM_CPPCR & CPM_CPPCR_PLLOD_MASK) >> CPM_CPPCR_PLLOD_BIT static unsigned cpm_get_cdiv (): return (CPM_CPCCR & CPM_CPCCR_CDIV_MASK) >> CPM_CPCCR_CDIV_BIT static unsigned cpm_get_hdiv (): return (CPM_CPCCR & CPM_CPCCR_HDIV_MASK) >> CPM_CPCCR_HDIV_BIT static unsigned cpm_get_pdiv (): return (CPM_CPCCR & CPM_CPCCR_PDIV_MASK) >> CPM_CPCCR_PDIV_BIT static unsigned cpm_get_mdiv (): return (CPM_CPCCR & CPM_CPCCR_MDIV_MASK) >> CPM_CPCCR_MDIV_BIT static unsigned cpm_get_ldiv (): return (CPM_CPCCR & CPM_CPCCR_LDIV_MASK) >> CPM_CPCCR_LDIV_BIT static unsigned cpm_get_udiv (): return (CPM_CPCCR & CPM_CPCCR_UDIV_MASK) >> CPM_CPCCR_UDIV_BIT static unsigned cpm_get_i2sdiv (): return (CPM_I2SCDR & CPM_I2SCDR_I2SDIV_MASK) >> CPM_I2SCDR_I2SDIV_BIT static unsigned cpm_get_pixdiv (): return (CPM_LPCDR & CPM_LPCDR_PIXDIV_MASK) >> CPM_LPCDR_PIXDIV_BIT static unsigned cpm_get_mscdiv (): return (CPM_MSCCDR & CPM_MSCCDR_MSCDIV_MASK) >> CPM_MSCCDR_MSCDIV_BIT static unsigned cpm_get_uhcdiv (): return (CPM_UHCCDR & CPM_UHCCDR_UHCDIV_MASK) >> CPM_UHCCDR_UHCDIV_BIT static unsigned cpm_get_ssidiv (): return (CPM_SSICDR & CPM_SSICDR_SSIDIV_MASK) >> CPM_SSICDR_SSIDIV_BIT static void cpm_set_cdiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_CDIV_MASK) | (v << (CPM_CPCCR_CDIV_BIT)) static void cpm_set_hdiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_HDIV_MASK) | (v << (CPM_CPCCR_HDIV_BIT)) static void cpm_set_pdiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_PDIV_MASK) | (v << (CPM_CPCCR_PDIV_BIT)) static void cpm_set_mdiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_MDIV_MASK) | (v << (CPM_CPCCR_MDIV_BIT)) static void cpm_set_ldiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_LDIV_MASK) | (v << (CPM_CPCCR_LDIV_BIT)) static void cpm_set_udiv (unsigned v): CPM_CPCCR = (CPM_CPCCR & ~CPM_CPCCR_UDIV_MASK) | (v << (CPM_CPCCR_UDIV_BIT)) static void cpm_set_i2sdiv (unsigned v): CPM_I2SCDR = (CPM_I2SCDR & ~CPM_I2SCDR_I2SDIV_MASK) | (v << (CPM_I2SCDR_I2SDIV_BIT)) static void cpm_set_pixdiv (unsigned v): CPM_LPCDR = (CPM_LPCDR & ~CPM_LPCDR_PIXDIV_MASK) | (v << (CPM_LPCDR_PIXDIV_BIT)) static void cpm_set_mscdiv (unsigned v): CPM_MSCCDR = (CPM_MSCCDR & ~CPM_MSCCDR_MSCDIV_MASK) | (v << (CPM_MSCCDR_MSCDIV_BIT)) static void cpm_set_uhcdiv (unsigned v): CPM_UHCCDR = (CPM_UHCCDR & ~CPM_UHCCDR_UHCDIV_MASK) | (v << (CPM_UHCCDR_UHCDIV_BIT)) static void cpm_ssiclk_select_exclk (): CPM_SSICDR &= ~CPM_SSICDR_SCS static void cpm_ssiclk_select_pllout (): CPM_SSICDR |= CPM_SSICDR_SCS static void cpm_set_ssidiv (unsigned v): CPM_SSICDR = (CPM_SSICDR & ~CPM_SSICDR_SSIDIV_MASK) | ((v) << (CPM_SSICDR_SSIDIV_BIT)) #define cpm_select_i2sclk_exclk() (CPM_CPCCR &= ~CPM_CPCCR_I2CS) #define cpm_select_i2sclk_pll() (CPM_CPCCR |= CPM_CPCCR_I2CS) #define cpm_enable_cko() (CPM_CPCCR |= CPM_CPCCR_CLKOEN) #define cpm_select_usbclk_exclk() (CPM_CPCCR &= ~CPM_CPCCR_UCS) #define cpm_select_usbclk_pll() (CPM_CPCCR |= CPM_CPCCR_UCS) #define cpm_enable_pll_change() (CPM_CPCCR |= CPM_CPCCR_CE) #define cpm_pllout_direct() (CPM_CPCCR |= CPM_CPCCR_PCS) #define cpm_pllout_div2() (CPM_CPCCR &= ~CPM_CPCCR_PCS) #define cpm_pll_is_on() (CPM_CPPCR & CPM_CPPCR_PLLS) #define cpm_pll_bypass() (CPM_CPPCR |= CPM_CPPCR_PLLBP) #define cpm_pll_enable() (CPM_CPPCR |= CPM_CPPCR_PLLEN) #define cpm_get_cclk_doze_duty() ((CPM_LCR & CPM_LCR_DOZE_DUTY_MASK) >> CPM_LCR_DOZE_DUTY_BIT) #define cpm_set_cclk_doze_duty(v) (CPM_LCR = (CPM_LCR & ~CPM_LCR_DOZE_DUTY_MASK) | ((v) << (CPM_LCR_DOZE_DUTY_BIT))) #define cpm_doze_mode() (CPM_LCR |= CPM_LCR_DOZE_ON) #define cpm_idle_mode() (CPM_LCR = (CPM_LCR & ~CPM_LCR_LPM_MASK) | CPM_LCR_LPM_IDLE) #define cpm_sleep_mode() (CPM_LCR = (CPM_LCR & ~CPM_LCR_LPM_MASK) | CPM_LCR_LPM_SLEEP) #define cpm_stop_all() (CPM_CLKGR = 0x7fff) #define cpm_stop_uart1() (CPM_CLKGR |= CPM_CLKGR_UART1) #define cpm_stop_uhc() (CPM_CLKGR |= CPM_CLKGR_UHC) #define cpm_stop_ipu() (CPM_CLKGR |= CPM_CLKGR_IPU) #define cpm_stop_dmac() (CPM_CLKGR |= CPM_CLKGR_DMAC) #define cpm_stop_udc() (CPM_CLKGR |= CPM_CLKGR_UDC) #define cpm_stop_lcd() (CPM_CLKGR |= CPM_CLKGR_LCD) #define cpm_stop_cim() (CPM_CLKGR |= CPM_CLKGR_CIM) #define cpm_stop_sadc() (CPM_CLKGR |= CPM_CLKGR_SADC) #define cpm_stop_msc() (CPM_CLKGR |= CPM_CLKGR_MSC) #define cpm_stop_aic1() (CPM_CLKGR |= CPM_CLKGR_AIC1) #define cpm_stop_aic2() (CPM_CLKGR |= CPM_CLKGR_AIC2) #define cpm_stop_ssi() (CPM_CLKGR |= CPM_CLKGR_SSI) #define cpm_stop_i2c() (CPM_CLKGR |= CPM_CLKGR_I2C) #define cpm_stop_rtc() (CPM_CLKGR |= CPM_CLKGR_RTC) #define cpm_stop_tcu() (CPM_CLKGR |= CPM_CLKGR_TCU) #define cpm_stop_uart0() (CPM_CLKGR |= CPM_CLKGR_UART0) #define cpm_start_all() (CPM_CLKGR = 0x0) #define cpm_start_uart1() (CPM_CLKGR &= ~CPM_CLKGR_UART1) #define cpm_start_uhc() (CPM_CLKGR &= ~CPM_CLKGR_UHC) #define cpm_start_ipu() (CPM_CLKGR &= ~CPM_CLKGR_IPU) #define cpm_start_dmac() (CPM_CLKGR &= ~CPM_CLKGR_DMAC) #define cpm_start_udc() (CPM_CLKGR &= ~CPM_CLKGR_UDC) #define cpm_start_lcd() (CPM_CLKGR &= ~CPM_CLKGR_LCD) #define cpm_start_cim() (CPM_CLKGR &= ~CPM_CLKGR_CIM) #define cpm_start_sadc() (CPM_CLKGR &= ~CPM_CLKGR_SADC) #define cpm_start_msc() (CPM_CLKGR &= ~CPM_CLKGR_MSC) #define cpm_start_aic1() (CPM_CLKGR &= ~CPM_CLKGR_AIC1) #define cpm_start_aic2() (CPM_CLKGR &= ~CPM_CLKGR_AIC2) #define cpm_start_ssi() (CPM_CLKGR &= ~CPM_CLKGR_SSI) #define cpm_start_i2c() (CPM_CLKGR &= ~CPM_CLKGR_I2C) #define cpm_start_rtc() (CPM_CLKGR &= ~CPM_CLKGR_RTC) #define cpm_start_tcu() (CPM_CLKGR &= ~CPM_CLKGR_TCU) #define cpm_start_uart0() (CPM_CLKGR &= ~CPM_CLKGR_UART0) #define cpm_get_o1st() ((CPM_SCR & CPM_SCR_O1ST_MASK) >> CPM_SCR_O1ST_BIT) #define cpm_set_o1st(v) (CPM_SCR = (CPM_SCR & ~CPM_SCR_O1ST_MASK) | ((v) << (CPM_SCR_O1ST_BIT))) #define cpm_suspend_usbphy() (CPM_SCR |= CPM_SCR_USBPHY_SUSPEND) #define cpm_enable_osc_in_sleep() (CPM_SCR |= CPM_SCR_OSC_ENABLE) // PLL output frequency static unsigned cpm_get_pllout (): unsigned m, n, no, pllout unsigned cppcr = CPM_CPPCR unsigned od[4] = {1, 2, 2, 4} if (cppcr & CPM_CPPCR_PLLEN) && !(cppcr & CPM_CPPCR_PLLBP): m = cpm_get_pllm () + 2 n = cpm_get_plln () + 2 no = od[cpm_get_pllod ()] pllout = JZ_EXTAL * m / n / no else: pllout = JZ_EXTAL return pllout // PLL output frequency for MSC/I2S/LCD/USB static unsigned cpm_get_pllout2 (): if CPM_CPCCR & CPM_CPCCR_PCS: return cpm_get_pllout () else: return cpm_get_pllout () / 2 // CPU core clock static unsigned cpm_get_cclk (): int div[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32} return cpm_get_pllout () / div[cpm_get_cdiv ()] // AHB system bus clock static unsigned cpm_get_hclk (): int div[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32} return cpm_get_pllout () / div[cpm_get_hdiv ()] // Memory bus clock static unsigned cpm_get_mclk (): int div[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32} return cpm_get_pllout () / div[cpm_get_mdiv ()] // APB peripheral bus clock static unsigned cpm_get_pclk (): int div[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32} return cpm_get_pllout () / div[cpm_get_pdiv ()] // LCDC module clock static unsigned cpm_get_lcdclk (): return cpm_get_pllout2 () / (cpm_get_ldiv () + 1) // LCD pixel clock static unsigned cpm_get_pixclk (): return cpm_get_pllout2 () / (cpm_get_pixdiv () + 1) // I2S clock static unsigned cpm_get_i2sclk (): if CPM_CPCCR & CPM_CPCCR_I2CS: return cpm_get_pllout2 () / (cpm_get_i2sdiv () + 1) else: return JZ_EXTAL // USB clock static unsigned cpm_get_usbclk (): if CPM_CPCCR & CPM_CPCCR_UCS: return cpm_get_pllout2 () / (cpm_get_udiv () + 1) else: return JZ_EXTAL // MSC clock static unsigned cpm_get_mscclk (): return cpm_get_pllout2 () / (cpm_get_mscdiv () + 1) // EXTAL clock for UART,I2C,SSI,TCU,USB-PHY static unsigned cpm_get_extalclk (): return JZ_EXTAL // RTC clock for CPM,INTC,RTC,TCU,WDT static unsigned cpm_get_rtcclk (): return RTC_CLOCK // Output 24MHz for SD and 16MHz for MMC. static inline void cpm_select_msc_clk (int sd): unsigned int pllout2 = cpm_get_pllout2 () unsigned int div = 0 if sd: div = pllout2 / 24000000 else: div = pllout2 / 16000000 CPM_MSCCDR = div - 1 //************************************************************************** // TCU //************************************************************************** // where 'n' is the TCU channel #define tcu_select_extalclk(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~(TCU_TCSR_EXT_EN | TCU_TCSR_RTC_EN | TCU_TCSR_PCK_EN)) | TCU_TCSR_EXT_EN) #define tcu_select_rtcclk(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~(TCU_TCSR_EXT_EN | TCU_TCSR_RTC_EN | TCU_TCSR_PCK_EN)) | TCU_TCSR_RTC_EN) #define tcu_select_pclk(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~(TCU_TCSR_EXT_EN | TCU_TCSR_RTC_EN | TCU_TCSR_PCK_EN)) | TCU_TCSR_PCK_EN) #define tcu_select_clk_div1(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE1) #define tcu_select_clk_div4(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE4) #define tcu_select_clk_div16(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE16) #define tcu_select_clk_div64(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE64) #define tcu_select_clk_div256(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE256) #define tcu_select_clk_div1024(n) (TCU_TCSR((n)) = (TCU_TCSR((n)) & ~TCU_TCSR_PRESCALE_MASK) | TCU_TCSR_PRESCALE1024) #define tcu_enable_pwm_output(n) ( TCU_TCSR((n)) |= TCU_TCSR_PWM_EN ) #define tcu_disable_pwm_output(n) ( TCU_TCSR((n)) &= ~TCU_TCSR_PWM_EN ) #define tcu_init_pwm_output_high(n) ( TCU_TCSR((n)) |= TCU_TCSR_PWM_INITL_HIGH ) #define tcu_init_pwm_output_low(n) ( TCU_TCSR((n)) &= ~TCU_TCSR_PWM_INITL_HIGH ) #define tcu_set_pwm_output_shutdown_graceful(n) ( TCU_TCSR((n)) &= ~TCU_TCSR_PWM_SD ) #define tcu_set_pwm_output_shutdown_abrupt(n) ( TCU_TCSR((n)) |= TCU_TCSR_PWM_SD ) #define tcu_start_counter(n) ( TCU_TESR |= (1 << (n)) ) #define tcu_stop_counter(n) ( TCU_TECR |= (1 << (n)) ) #define tcu_half_match_flag(n) ( TCU_TFR & (1 << ((n) + 16)) ) #define tcu_full_match_flag(n) ( TCU_TFR & (1 << (n)) ) #define tcu_set_half_match_flag(n) ( TCU_TFSR = (1 << ((n) + 16)) ) #define tcu_set_full_match_flag(n) ( TCU_TFSR = (1 << (n)) ) #define tcu_clear_half_match_flag(n) ( TCU_TFCR = (1 << ((n) + 16)) ) #define tcu_clear_full_match_flag(n) ( TCU_TFCR = (1 << (n)) ) #define tcu_mask_half_match_irq(n) ( TCU_TMSR = (1 << ((n) + 16)) ) #define tcu_mask_full_match_irq(n) ( TCU_TMSR = (1 << (n)) ) #define tcu_unmask_half_match_irq(n) ( TCU_TMCR = (1 << ((n) + 16)) ) #define tcu_unmask_full_match_irq(n) ( TCU_TMCR = (1 << (n)) ) #define tcu_wdt_clock_stopped() ( TCU_TSR & TCU_TSSR_WDTSC ) #define tcu_timer_clock_stopped(n) ( TCU_TSR & (1 << (n)) ) #define tcu_start_wdt_clock() ( TCU_TSCR = TCU_TSSR_WDTSC ) #define tcu_start_timer_clock(n) ( TCU_TSCR = (1 << (n)) ) #define tcu_stop_wdt_clock() ( TCU_TSSR = TCU_TSSR_WDTSC ) #define tcu_stop_timer_clock(n) ( TCU_TSSR = (1 << (n)) ) #define tcu_get_count(n) ( TCU_TCNT((n)) ) #define tcu_set_count(n,v) ( TCU_TCNT((n)) = (v) ) #define tcu_set_full_data(n,v) ( TCU_TDFR((n)) = (v) ) #define tcu_set_half_data(n,v) ( TCU_TDHR((n)) = (v) ) //************************************************************************** // WDT //************************************************************************** #define wdt_start() ( WDT_TCER |= WDT_TCER_TCEN ) #define wdt_stop() ( WDT_TCER &= ~WDT_TCER_TCEN ) #define wdt_set_count(v) ( WDT_TCNT = (v) ) #define wdt_set_data(v) ( WDT_TDR = (v) ) #define wdt_select_extalclk() (WDT_TCSR = (WDT_TCSR & ~(WDT_TCSR_EXT_EN | WDT_TCSR_RTC_EN | WDT_TCSR_PCK_EN)) | WDT_TCSR_EXT_EN) #define wdt_select_rtcclk() (WDT_TCSR = (WDT_TCSR & ~(WDT_TCSR_EXT_EN | WDT_TCSR_RTC_EN | WDT_TCSR_PCK_EN)) | WDT_TCSR_RTC_EN) #define wdt_select_pclk() (WDT_TCSR = (WDT_TCSR & ~(WDT_TCSR_EXT_EN | WDT_TCSR_RTC_EN | WDT_TCSR_PCK_EN)) | WDT_TCSR_PCK_EN) #define wdt_select_clk_div1() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE1) #define wdt_select_clk_div4() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE4) #define wdt_select_clk_div16() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE16) #define wdt_select_clk_div64() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE64) #define wdt_select_clk_div256() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE256) #define wdt_select_clk_div1024() (WDT_TCSR = (WDT_TCSR & ~WDT_TCSR_PRESCALE_MASK) | WDT_TCSR_PRESCALE1024) //************************************************************************** // UART //************************************************************************** #define uart_enable(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_FCR) |= UARTFCR_UUE | UARTFCR_FE ) #define uart_disable(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_FCR) = ~UARTFCR_UUE ) #define uart_enable_transmit_irq(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_IER) |= UARTIER_TIE ) #define uart_disable_transmit_irq(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_IER) &= ~UARTIER_TIE ) #define uart_enable_receive_irq(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_IER) |= UARTIER_RIE | UARTIER_RLIE | UARTIER_RTIE ) #define uart_disable_receive_irq(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_IER) &= ~(UARTIER_RIE | UARTIER_RLIE | UARTIER_RTIE) ) #define uart_enable_loopback(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_MCR) |= UARTMCR_LOOP ) #define uart_disable_loopback(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_MCR) &= ~UARTMCR_LOOP ) #define uart_set_8n1(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_LCR) = UARTLCR_WLEN_8 ) static void uart_set_baud (unsigned n, unsigned devclk, unsigned baud): REG8 (UART_BASE + UART_OFF*(n) + OFF_LCR) |= UARTLCR_DLAB REG8 (UART_BASE + UART_OFF*(n) + OFF_DLLR) = (devclk / 16 / baud) & 0xff REG8 (UART_BASE + UART_OFF*(n) + OFF_DLHR) = ((devclk / 16 / baud) >> 8) & 0xff REG8 (UART_BASE + UART_OFF*(n) + OFF_LCR) &= ~UARTLCR_DLAB #define uart_parity_error(n) ( (REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) & UARTLSR_PER) != 0 ) #define uart_clear_errors(n) ( REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) &= ~(UARTLSR_ORER | UARTLSR_BRK | UARTLSR_FER | UARTLSR_PER | UARTLSR_RFER) ) #define uart_transmit_fifo_empty(n) ( (REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) & UARTLSR_TDRQ) != 0 ) #define uart_transmit_end(n) ( (REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) & UARTLSR_TEMT) != 0 ) #define uart_transmit_char(n, ch) REG8(UART_BASE + UART_OFF*(n) + OFF_TDR) = (ch) #define uart_receive_fifo_full(n) ( (REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) & UARTLSR_DR) != 0 ) #define uart_receive_ready(n) ( (REG8(UART_BASE + UART_OFF*(n) + OFF_LSR) & UARTLSR_DR) != 0 ) #define uart_receive_char(n) REG8(UART_BASE + UART_OFF*(n) + OFF_RDR) #define uart_disable_irda() ( REG8(IRDA_BASE + OFF_SIRCR) &= ~(SIRCR_TSIRE | SIRCR_RSIRE) ) #define uart_enable_irda() /* Tx high pulse as 0, Rx low pulse as 0 */ ( REG8(IRDA_BASE + OFF_SIRCR) = SIRCR_TSIRE | SIRCR_RSIRE | SIRCR_RXPL | SIRCR_TPWS ) //************************************************************************** // DMAC //************************************************************************** // n is the DMA channel (0 - 5) #define dmac_enable_module() ( DMAC_DMACR |= DMAC_DMACR_DMAE | DMAC_DMACR_PR_RR ) #define dmac_disable_module() ( DMAC_DMACR &= ~DMAC_DMACR_DMAE ) // p=0,1,2,3 static void dmac_set_priority (unsigned p): DMAC_DMACR &= ~DMAC_DMACR_PR_MASK DMAC_DMACR |= ((p) << DMAC_DMACR_PR_BIT) #define dmac_test_halt_error() ( DMAC_DMACR & DMAC_DMACR_HLT ) #define dmac_test_addr_error() ( DMAC_DMACR & DMAC_DMACR_AR ) #define dmac_enable_descriptor(n) ( DMAC_DCCSR((n)) &= ~DMAC_DCCSR_NDES ) #define dmac_disable_descriptor(n) ( DMAC_DCCSR((n)) |= DMAC_DCCSR_NDES ) #define dmac_enable_channel(n) ( DMAC_DCCSR((n)) |= DMAC_DCCSR_EN ) #define dmac_disable_channel(n) ( DMAC_DCCSR((n)) &= ~DMAC_DCCSR_EN ) #define dmac_channel_enabled(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_EN ) #define dmac_channel_enable_irq(n) ( DMAC_DCMD((n)) |= DMAC_DCMD_TIE ) #define dmac_channel_disable_irq(n) ( DMAC_DCMD((n)) &= ~DMAC_DCMD_TIE ) #define dmac_channel_transmit_halt_detected(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_HLT ) #define dmac_channel_transmit_end_detected(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_TT ) #define dmac_channel_address_error_detected(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_AR ) #define dmac_channel_count_terminated_detected(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_CT ) #define dmac_channel_descriptor_invalid_detected(n) ( DMAC_DCCSR((n)) & DMAC_DCCSR_INV ) #define dmac_channel_clear_transmit_halt(n) ( DMAC_DCCSR(n) &= ~DMAC_DCCSR_HLT ) #define dmac_channel_clear_transmit_end(n) ( DMAC_DCCSR(n) &= ~DMAC_DCCSR_TT ) #define dmac_channel_clear_address_error(n) ( DMAC_DCCSR(n) &= ~DMAC_DCCSR_AR ) #define dmac_channel_clear_count_terminated(n) ( DMAC_DCCSR((n)) &= ~DMAC_DCCSR_CT ) #define dmac_channel_clear_descriptor_invalid(n) ( DMAC_DCCSR((n)) &= ~DMAC_DCCSR_INV ) #define dmac_channel_set_single_mode(n) ( DMAC_DCMD((n)) &= ~DMAC_DCMD_TM ) #define dmac_channel_set_block_mode(n) ( DMAC_DCMD((n)) |= DMAC_DCMD_TM ) static void dmac_channel_set_transfer_unit_32bit (unsigned n): DMAC_DCMD((n)) &= ~DMAC_DCMD_DS_MASK DMAC_DCMD((n)) |= DMAC_DCMD_DS_32BIT static void dmac_channel_set_transfer_unit_16bit (unsigned n): DMAC_DCMD((n)) &= ~DMAC_DCMD_DS_MASK DMAC_DCMD((n)) |= DMAC_DCMD_DS_16BIT static void dmac_channel_set_transfer_unit_8bit (unsigned n): DMAC_DCMD((n)) &= ~DMAC_DCMD_DS_MASK DMAC_DCMD((n)) |= DMAC_DCMD_DS_8BIT static void dmac_channel_set_transfer_unit_16byte (unsigned n): DMAC_DCMD((n)) &= ~DMAC_DCMD_DS_MASK DMAC_DCMD((n)) |= DMAC_DCMD_DS_16BYTE static void dmac_channel_set_transfer_unit_32byte (unsigned n): DMAC_DCMD((n)) &= ~DMAC_DCMD_DS_MASK DMAC_DCMD((n)) |= DMAC_DCMD_DS_32BYTE // w=8,16,32 #define dmac_channel_set_dest_port_width(n,w) do { DMAC_DCMD((n)) &= ~DMAC_DCMD_DWDH_MASK; DMAC_DCMD((n)) |= DMAC_DCMD_DWDH_##w; } while (0) // w=8,16,32 #define dmac_channel_set_src_port_width(n,v) do { DMAC_DCMD((n)) &= ~DMAC_DCMD_SWDH_MASK; DMAC_DCMD((n)) |= DMAC_DCMD_SWDH_##w; } while (0) // v=0-15 static void dmac_channel_set_rdil(unsigned n, unsigned v): DMAC_DCMD((n)) &= ~DMAC_DCMD_RDIL_MASK DMAC_DCMD((n)) |= ((v) << DMAC_DCMD_RDIL_BIT) #define dmac_channel_dest_addr_fixed(n) ( DMAC_DCMD((n)) &= ~DMAC_DCMD_DAI ) #define dmac_channel_dest_addr_increment(n) ( DMAC_DCMD((n)) |= DMAC_DCMD_DAI ) #define dmac_channel_src_addr_fixed(n) ( DMAC_DCMD((n)) &= ~DMAC_DCMD_SAI ) #define dmac_channel_src_addr_increment(n) ( DMAC_DCMD((n)) |= DMAC_DCMD_SAI ) #define dmac_channel_set_doorbell(n) ( DMAC_DMADBSR = (1 << (n)) ) #define dmac_channel_irq_detected(n) ( DMAC_DMAIPR & (1 << (n)) ) #define dmac_channel_ack_irq(n) ( DMAC_DMAIPR &= ~(1 << (n)) ) //************************************************************************** // AIC (AC'97 & I2S Controller) //************************************************************************** #define aic_enable() ( AIC_FR |= AIC_FR_ENB ) #define aic_disable() ( AIC_FR &= ~AIC_FR_ENB ) #define aic_select_ac97() ( AIC_FR &= ~AIC_FR_AUSEL ) #define aic_select_i2s() ( AIC_FR |= AIC_FR_AUSEL ) #define aic_play_zero() ( AIC_FR &= ~AIC_FR_LSMP ) #define aic_play_lastsample() ( AIC_FR |= AIC_FR_LSMP ) #define i2s_as_master() ( AIC_FR |= AIC_FR_BCKD | AIC_FR_SYNCD ) #define i2s_as_slave() ( AIC_FR &= ~(AIC_FR_BCKD | AIC_FR_SYNCD) ) #define aic_reset_status() ( AIC_FR & AIC_FR_RST ) static void aic_reset(): AIC_FR |= AIC_FR_RST static void aic_set_transmit_trigger (unsigned n): AIC_FR &= ~AIC_FR_TFTH_MASK AIC_FR |= ((n) << AIC_FR_TFTH_BIT) static void aic_set_receive_trigger (unsigned n): AIC_FR &= ~AIC_FR_RFTH_MASK AIC_FR |= ((n) << AIC_FR_RFTH_BIT) #define aic_enable_record() ( AIC_CR |= AIC_CR_EREC ) #define aic_disable_record() ( AIC_CR &= ~AIC_CR_EREC ) #define aic_enable_replay() ( AIC_CR |= AIC_CR_ERPL ) #define aic_disable_replay() ( AIC_CR &= ~AIC_CR_ERPL ) #define aic_enable_loopback() ( AIC_CR |= AIC_CR_ENLBF ) #define aic_disable_loopback() ( AIC_CR &= ~AIC_CR_ENLBF ) #define aic_flush_fifo() ( AIC_CR |= AIC_CR_FLUSH ) #define aic_unflush_fifo() ( AIC_CR &= ~AIC_CR_FLUSH ) #define aic_enable_transmit_intr() ( AIC_CR |= (AIC_CR_ETFS | AIC_CR_ETUR) ) #define aic_disable_transmit_intr() ( AIC_CR &= ~(AIC_CR_ETFS | AIC_CR_ETUR) ) #define aic_enable_receive_intr() ( AIC_CR |= (AIC_CR_ERFS | AIC_CR_EROR) ) #define aic_disable_receive_intr() ( AIC_CR &= ~(AIC_CR_ERFS | AIC_CR_EROR) ) #define aic_enable_transmit_dma() ( AIC_CR |= AIC_CR_TDMS ) #define aic_disable_transmit_dma() ( AIC_CR &= ~AIC_CR_TDMS ) #define aic_enable_receive_dma() ( AIC_CR |= AIC_CR_RDMS ) #define aic_disable_receive_dma() ( AIC_CR &= ~AIC_CR_RDMS ) #define aic_enable_mono2stereo() ( AIC_CR |= AIC_CR_M2S ) #define aic_disable_mono2stereo() ( AIC_CR &= ~AIC_CR_M2S ) #define aic_enable_byteswap() ( AIC_CR |= AIC_CR_ENDSW ) #define aic_disable_byteswap() ( AIC_CR &= ~AIC_CR_ENDSW ) #define aic_enable_unsignadj() ( AIC_CR |= AIC_CR_AVSTSU ) #define aic_disable_unsignadj() ( AIC_CR &= ~AIC_CR_AVSTSU ) #define AC97_PCM_XS_L_FRONT AIC_ACCR1_XS_SLOT3 #define AC97_PCM_XS_R_FRONT AIC_ACCR1_XS_SLOT4 #define AC97_PCM_XS_CENTER AIC_ACCR1_XS_SLOT6 #define AC97_PCM_XS_L_SURR AIC_ACCR1_XS_SLOT7 #define AC97_PCM_XS_R_SURR AIC_ACCR1_XS_SLOT8 #define AC97_PCM_XS_LFE AIC_ACCR1_XS_SLOT9 #define AC97_PCM_RS_L_FRONT AIC_ACCR1_RS_SLOT3 #define AC97_PCM_RS_R_FRONT AIC_ACCR1_RS_SLOT4 #define AC97_PCM_RS_CENTER AIC_ACCR1_RS_SLOT6 #define AC97_PCM_RS_L_SURR AIC_ACCR1_RS_SLOT7 #define AC97_PCM_RS_R_SURR AIC_ACCR1_RS_SLOT8 #define AC97_PCM_RS_LFE AIC_ACCR1_RS_SLOT9 #define ac97_set_xs_none() ( AIC_ACCR1 &= ~AIC_ACCR1_XS_MASK ) static void ac97_set_xs_mono(): AIC_ACCR1 &= ~AIC_ACCR1_XS_MASK AIC_ACCR1 |= AC97_PCM_XS_R_FRONT static void ac97_set_xs_stereo(): AIC_ACCR1 &= ~AIC_ACCR1_XS_MASK AIC_ACCR1 |= AC97_PCM_XS_L_FRONT | AC97_PCM_XS_R_FRONT // In fact, only stereo is support now. #define ac97_set_rs_none() ( AIC_ACCR1 &= ~AIC_ACCR1_RS_MASK ) static void ac97_set_rs_mono(): AIC_ACCR1 &= ~AIC_ACCR1_RS_MASK AIC_ACCR1 |= AC97_PCM_RS_R_FRONT static void ac97_set_rs_stereo(): AIC_ACCR1 &= ~AIC_ACCR1_RS_MASK AIC_ACCR1 |= AC97_PCM_RS_L_FRONT | AC97_PCM_RS_R_FRONT static void ac97_warm_reset_codec(): AIC_ACCR2 |= AIC_ACCR2_SA AIC_ACCR2 |= AIC_ACCR2_SS //udelay(2) // TODO AIC_ACCR2 &= ~AIC_ACCR2_SS AIC_ACCR2 &= ~AIC_ACCR2_SA static void ac97_cold_reset_codec(): AIC_ACCR2 |= AIC_ACCR2_SR //udelay(2) // TODO AIC_ACCR2 &= ~AIC_ACCR2_SR // n=8,16,18,20 #define ac97_set_iass(n) ( AIC_ACCR2 = (AIC_ACCR2 & ~AIC_ACCR2_IASS_MASK) | AIC_ACCR2_IASS_##n##BIT ) #define ac97_set_oass(n) ( AIC_ACCR2 = (AIC_ACCR2 & ~AIC_ACCR2_OASS_MASK) | AIC_ACCR2_OASS_##n##BIT ) #define i2s_select_i2s() ( AIC_I2SCR &= ~AIC_I2SCR_AMSL ) #define i2s_select_msbjustified() ( AIC_I2SCR |= AIC_I2SCR_AMSL ) // n=8,16,18,20,24 //#define i2s_set_sample_size(n) ( AIC_I2SCR |= (AIC_I2SCR & ~AIC_I2SCR_WL_MASK) | AIC_I2SCR_WL_##n##BIT ) #define i2s_set_oss_sample_size(n) ( AIC_CR = (AIC_CR & ~AIC_CR_OSS_MASK) | AIC_CR_OSS_##n##BIT ) #define i2s_set_iss_sample_size(n) ( AIC_CR = (AIC_CR & ~AIC_CR_ISS_MASK) | AIC_CR_ISS_##n##BIT ) #define i2s_stop_bitclk() ( AIC_I2SCR |= AIC_I2SCR_STPBK ) #define i2s_start_bitclk() ( AIC_I2SCR &= ~AIC_I2SCR_STPBK ) #define aic_transmit_request() ( AIC_SR & AIC_SR_TFS ) #define aic_receive_request() ( AIC_SR & AIC_SR_RFS ) #define aic_transmit_underrun() ( AIC_SR & AIC_SR_TUR ) #define aic_receive_overrun() ( AIC_SR & AIC_SR_ROR ) #define aic_clear_errors() ( AIC_SR &= ~(AIC_SR_TUR | AIC_SR_ROR) ) #define aic_get_transmit_resident() ( (AIC_SR & AIC_SR_TFL_MASK) >> AIC_SR_TFL_BIT ) #define aic_get_receive_count() ( (AIC_SR & AIC_SR_RFL_MASK) >> AIC_SR_RFL_BIT ) #define ac97_command_transmitted() ( AIC_ACSR & AIC_ACSR_CADT ) #define ac97_status_received() ( AIC_ACSR & AIC_ACSR_SADR ) #define ac97_status_receive_timeout() ( AIC_ACSR & AIC_ACSR_RSTO ) #define ac97_codec_is_low_power_mode() ( AIC_ACSR & AIC_ACSR_CLPM ) #define ac97_codec_is_ready() ( AIC_ACSR & AIC_ACSR_CRDY ) #define ac97_slot_error_detected() ( AIC_ACSR & AIC_ACSR_SLTERR ) #define ac97_clear_slot_error() ( AIC_ACSR &= ~AIC_ACSR_SLTERR ) #define i2s_is_busy() ( AIC_I2SSR & AIC_I2SSR_BSY ) #define CODEC_READ_CMD (1 << 19) #define CODEC_WRITE_CMD (0 << 19) #define CODEC_REG_INDEX_BIT 12 #define CODEC_REG_INDEX_MASK (0x7f << CODEC_REG_INDEX_BIT) // 18:12 #define CODEC_REG_DATA_BIT 4 #define CODEC_REG_DATA_MASK (0x0ffff << 4) // 19:4 #define ac97_out_rcmd_addr(reg) (AIC_ACCAR = CODEC_READ_CMD | ((reg) << CODEC_REG_INDEX_BIT)) #define ac97_out_wcmd_addr(reg) (AIC_ACCAR = CODEC_WRITE_CMD | ((reg) << CODEC_REG_INDEX_BIT)) #define ac97_out_data(value) (AIC_ACCDR = ((value) << CODEC_REG_DATA_BIT)) #define ac97_in_data() ( (AIC_ACSDR & CODEC_REG_DATA_MASK) >> CODEC_REG_DATA_BIT ) #define ac97_in_status_addr() ( (AIC_ACSAR & CODEC_REG_INDEX_MASK) >> CODEC_REG_INDEX_BIT ) #define i2s_set_sample_rate(i2sclk, sync) ( AIC_I2SDIV = ((i2sclk) / (4*64)) / (sync) ) #define aic_write_tfifo(v) ( AIC_DR = (v) ) #define aic_read_rfifo() ( AIC_DR ) #define aic_internal_codec() ( AIC_FR |= AIC_FR_ICDC ) #define aic_external_codec() ( AIC_FR &= ~AIC_FR_ICDC ) // // Define next ops for AC97 compatible // #define AC97_ACSR AIC_ACSR #define ac97_enable() aic_enable(); aic_select_ac97() #define ac97_disable() aic_disable() #define ac97_reset() aic_reset() #define ac97_set_transmit_trigger(n) aic_set_transmit_trigger(n) #define ac97_set_receive_trigger(n) aic_set_receive_trigger(n) #define ac97_enable_record() aic_enable_record() #define ac97_disable_record() aic_disable_record() #define ac97_enable_replay() aic_enable_replay() #define ac97_disable_replay() aic_disable_replay() #define ac97_enable_loopback() aic_enable_loopback() #define ac97_disable_loopback() aic_disable_loopback() #define ac97_enable_transmit_dma() aic_enable_transmit_dma() #define ac97_disable_transmit_dma() aic_disable_transmit_dma() #define ac97_enable_receive_dma() aic_enable_receive_dma() #define ac97_disable_receive_dma() aic_disable_receive_dma() #define ac97_transmit_request() aic_transmit_request() #define ac97_receive_request() aic_receive_request() #define ac97_transmit_underrun() aic_transmit_underrun() #define ac97_receive_overrun() aic_receive_overrun() #define ac97_clear_errors() aic_clear_errors() #define ac97_get_transmit_resident() aic_get_transmit_resident() #define ac97_get_receive_count() aic_get_receive_count() #define ac97_enable_transmit_intr() aic_enable_transmit_intr() #define ac97_disable_transmit_intr() aic_disable_transmit_intr() #define ac97_enable_receive_intr() aic_enable_receive_intr() #define ac97_disable_receive_intr() aic_disable_receive_intr() #define ac97_write_tfifo(v) aic_write_tfifo(v) #define ac97_read_rfifo() aic_read_rfifo() // // Define next ops for I2S compatible // #define I2S_ACSR AIC_I2SSR #define i2s_enable() aic_enable(); aic_select_i2s() #define i2s_disable() aic_disable() #define i2s_reset() aic_reset() #define i2s_set_transmit_trigger(n) aic_set_transmit_trigger(n) #define i2s_set_receive_trigger(n) aic_set_receive_trigger(n) #define i2s_enable_record() aic_enable_record() #define i2s_disable_record() aic_disable_record() #define i2s_enable_replay() aic_enable_replay() #define i2s_disable_replay() aic_disable_replay() #define i2s_enable_loopback() aic_enable_loopback() #define i2s_disable_loopback() aic_disable_loopback() #define i2s_enable_transmit_dma() aic_enable_transmit_dma() #define i2s_disable_transmit_dma() aic_disable_transmit_dma() #define i2s_enable_receive_dma() aic_enable_receive_dma() #define i2s_disable_receive_dma() aic_disable_receive_dma() #define i2s_transmit_request() aic_transmit_request() #define i2s_receive_request() aic_receive_request() #define i2s_transmit_underrun() aic_transmit_underrun() #define i2s_receive_overrun() aic_receive_overrun() #define i2s_clear_errors() aic_clear_errors() #define i2s_get_transmit_resident() aic_get_transmit_resident() #define i2s_get_receive_count() aic_get_receive_count() #define i2s_enable_transmit_intr() aic_enable_transmit_intr() #define i2s_disable_transmit_intr() aic_disable_transmit_intr() #define i2s_enable_receive_intr() aic_enable_receive_intr() #define i2s_disable_receive_intr() aic_disable_receive_intr() #define i2s_write_tfifo(v) aic_write_tfifo(v) #define i2s_read_rfifo() aic_read_rfifo() #define i2s_reset_codec() do { } while (0) static void aic_use_internal_codec (): aic_internal_codec () aic_select_i2s () i2s_as_slave () i2s_select_i2s () cpm_select_i2sclk_exclk () cpm_set_i2sdiv (1) //************************************************************************** // ICDC //************************************************************************** #define i2s_internal_codec() aic_internal_codec() #define i2s_external_codec() aic_external_codec() //************************************************************************** // INTC //************************************************************************** #define intc_unmask_irq(n) ( INTC_IMCR = (1 << (n)) ) #define intc_mask_irq(n) ( INTC_IMSR = (1 << (n)) ) #define intc_ack_irq(n) ( INTC_IPR = (1 << (n)) ) //************************************************************************** // I2C //************************************************************************** #define i2c_enable() ( I2C_CR |= I2C_CR_I2CE ) #define i2c_disable() ( I2C_CR &= ~I2C_CR_I2CE ) #define i2c_send_start() ( I2C_CR |= I2C_CR_STA ) #define i2c_send_stop() ( I2C_CR |= I2C_CR_STO ) #define i2c_send_ack() ( I2C_CR &= ~I2C_CR_AC ) #define i2c_send_nack() ( I2C_CR |= I2C_CR_AC ) #define i2c_set_drf() ( I2C_SR |= I2C_SR_DRF ) #define i2c_clear_drf() ( I2C_SR &= ~I2C_SR_DRF ) #define i2c_check_drf() ( I2C_SR & I2C_SR_DRF ) #define i2c_received_ack() ( !(I2C_SR & I2C_SR_ACKF) ) #define i2c_is_busy() ( I2C_SR & I2C_SR_BUSY ) #define i2c_transmit_ended() ( I2C_SR & I2C_SR_TEND ) #define i2c_set_clk(dev_clk, i2c_clk) ( I2C_GR = (dev_clk) / (16*(i2c_clk)) - 1 ) #define i2c_read() ( I2C_DR ) #define i2c_write(val) ( I2C_DR = (val) ) //************************************************************************** // MSC //************************************************************************** #define msc_start_op() ( MSC_STRPCL = MSC_STRPCL_START_OP | MSC_STRPCL_CLOCK_CONTROL_START ) #define msc_set_resto(to) ( MSC_RESTO = to ) #define msc_set_rdto(to) ( MSC_RDTO = to ) #define msc_set_cmd(cmd) ( MSC_CMD = cmd ) #define msc_set_arg(arg) ( MSC_ARG = arg ) #define msc_set_nob(nob) ( MSC_NOB = nob ) #define msc_get_nob() ( MSC_NOB ) #define msc_set_blklen(len) ( MSC_BLKLEN = len ) #define msc_set_cmdat(cmdat) ( MSC_CMDAT = cmdat ) #define msc_set_cmdat_ioabort() ( MSC_CMDAT |= MSC_CMDAT_IO_ABORT ) #define msc_clear_cmdat_ioabort() ( MSC_CMDAT &= ~MSC_CMDAT_IO_ABORT ) static void msc_set_cmdat_bus_width1(): MSC_CMDAT &= ~MSC_CMDAT_BUS_WIDTH_MASK MSC_CMDAT |= MSC_CMDAT_BUS_WIDTH_1BIT static void msc_set_cmdat_bus_width4(): MSC_CMDAT &= ~MSC_CMDAT_BUS_WIDTH_MASK MSC_CMDAT |= MSC_CMDAT_BUS_WIDTH_4BIT #define msc_set_cmdat_dma_en() ( MSC_CMDAT |= MSC_CMDAT_DMA_EN ) #define msc_set_cmdat_init() ( MSC_CMDAT |= MSC_CMDAT_INIT ) #define msc_set_cmdat_busy() ( MSC_CMDAT |= MSC_CMDAT_BUSY ) #define msc_set_cmdat_stream() ( MSC_CMDAT |= MSC_CMDAT_STREAM_BLOCK ) #define msc_set_cmdat_block() ( MSC_CMDAT &= ~MSC_CMDAT_STREAM_BLOCK ) #define msc_set_cmdat_read() ( MSC_CMDAT &= ~MSC_CMDAT_WRITE_READ ) #define msc_set_cmdat_write() ( MSC_CMDAT |= MSC_CMDAT_WRITE_READ ) #define msc_set_cmdat_data_en() ( MSC_CMDAT |= MSC_CMDAT_DATA_EN ) // r is MSC_CMDAT_RESPONSE_FORMAT_Rx or MSC_CMDAT_RESPONSE_FORMAT_NONE static void msc_set_cmdat_res_format(unsigned r): MSC_CMDAT &= ~MSC_CMDAT_RESPONSE_MASK MSC_CMDAT |= (r) #define msc_clear_cmdat() MSC_CMDAT &= ~( MSC_CMDAT_IO_ABORT | MSC_CMDAT_DMA_EN | MSC_CMDAT_INIT| MSC_CMDAT_BUSY | MSC_CMDAT_STREAM_BLOCK | MSC_CMDAT_WRITE_READ | MSC_CMDAT_DATA_EN | MSC_CMDAT_RESPONSE_MASK ) #define msc_get_imask() ( MSC_IMASK ) #define msc_mask_all_intrs() ( MSC_IMASK = 0xff ) #define msc_unmask_all_intrs() ( MSC_IMASK = 0x00 ) #define msc_mask_rd() ( MSC_IMASK |= MSC_IMASK_RXFIFO_RD_REQ ) #define msc_unmask_rd() ( MSC_IMASK &= ~MSC_IMASK_RXFIFO_RD_REQ ) #define msc_mask_wr() ( MSC_IMASK |= MSC_IMASK_TXFIFO_WR_REQ ) #define msc_unmask_wr() ( MSC_IMASK &= ~MSC_IMASK_TXFIFO_WR_REQ ) #define msc_mask_endcmdres() ( MSC_IMASK |= MSC_IMASK_END_CMD_RES ) #define msc_unmask_endcmdres() ( MSC_IMASK &= ~MSC_IMASK_END_CMD_RES ) #define msc_mask_datatrandone() ( MSC_IMASK |= MSC_IMASK_DATA_TRAN_DONE ) #define msc_unmask_datatrandone() ( MSC_IMASK &= ~MSC_IMASK_DATA_TRAN_DONE ) #define msc_mask_prgdone() ( MSC_IMASK |= MSC_IMASK_PRG_DONE ) #define msc_unmask_prgdone() ( MSC_IMASK &= ~MSC_IMASK_PRG_DONE ) // n=0,1,2,3,4,5,6,7 #define msc_set_clkrt(n) (MSC_CLKRT = n) #define msc_get_ireg() ( MSC_IREG ) #define msc_ireg_rd() ( MSC_IREG & MSC_IREG_RXFIFO_RD_REQ ) #define msc_ireg_wr() ( MSC_IREG & MSC_IREG_TXFIFO_WR_REQ ) #define msc_ireg_end_cmd_res() ( MSC_IREG & MSC_IREG_END_CMD_RES ) #define msc_ireg_data_tran_done() ( MSC_IREG & MSC_IREG_DATA_TRAN_DONE ) #define msc_ireg_prg_done() ( MSC_IREG & MSC_IREG_PRG_DONE ) #define msc_ireg_clear_end_cmd_res() ( MSC_IREG = MSC_IREG_END_CMD_RES ) #define msc_ireg_clear_data_tran_done() ( MSC_IREG = MSC_IREG_DATA_TRAN_DONE ) #define msc_ireg_clear_prg_done() ( MSC_IREG = MSC_IREG_PRG_DONE ) #define msc_get_stat() ( MSC_STAT ) #define msc_stat_not_end_cmd_res() ( (MSC_STAT & MSC_STAT_END_CMD_RES) == 0) #define msc_stat_crc_err() ( MSC_STAT & (MSC_STAT_CRC_RES_ERR | MSC_STAT_CRC_READ_ERROR | MSC_STAT_CRC_WRITE_ERROR_YES) ) #define msc_stat_res_crc_err() ( MSC_STAT & MSC_STAT_CRC_RES_ERR ) #define msc_stat_rd_crc_err() ( MSC_STAT & MSC_STAT_CRC_READ_ERROR ) #define msc_stat_wr_crc_err() ( MSC_STAT & MSC_STAT_CRC_WRITE_ERROR_YES ) #define msc_stat_resto_err() ( MSC_STAT & MSC_STAT_TIME_OUT_RES ) #define msc_stat_rdto_err() ( MSC_STAT & MSC_STAT_TIME_OUT_READ ) #define msc_rd_resfifo() ( MSC_RES ) #define msc_rd_rxfifo() ( MSC_RXFIFO ) #define msc_wr_txfifo(v) ( MSC_TXFIFO = v ) #define msc_start_clk() (MSC_STRPCL = MSC_STRPCL_CLOCK_CONTROL_START) #define MMC_CLK 19169200 #define SD_CLK 24576000 // msc_clk should little than pclk and little than clk retrieve from card static unsigned msc_calc_clk_divisor (bool sd, unsigned dev_clk, unsigned msc_clk): unsigned int rate, pclk, i pclk = dev_clk rate = sd ? SD_CLK : MMC_CLK if msc_clk && msc_clk < pclk: pclk = msc_clk i = 0 while pclk < rate: i ++ rate >>= 1 return i // divide rate to little than or equal to 400kHz static unsigned msc_calc_slow_clk_divisor (bool sd): unsigned rate, i rate = (sd ? SD_CLK : MMC_CLK) / 1000 / 400 i = 0 while rate > 0: rate >>= 1 ++i return i //************************************************************************** // SSI //************************************************************************** #define ssi_enable() ( SSI_CR0 |= SSI_CR0_SSIE ) #define ssi_disable() ( SSI_CR0 &= ~SSI_CR0_SSIE ) #define ssi_select_ce() ( SSI_CR0 &= ~SSI_CR0_FSEL ) #define ssi_normal_mode() ( SSI_ITR &= ~SSI_ITR_IVLTM_MASK ) static void ssi_select_ce2 (): SSI_CR0 |= SSI_CR0_FSEL SSI_CR1 &= ~SSI_CR1_MULTS static void ssi_select_gpc (): SSI_CR0 &= ~SSI_CR0_FSEL SSI_CR1 |= SSI_CR1_MULTS #define ssi_enable_tx_intr() ( SSI_CR0 |= SSI_CR0_TIE | SSI_CR0_TEIE ) #define ssi_disable_tx_intr() ( SSI_CR0 &= ~(SSI_CR0_TIE | SSI_CR0_TEIE) ) #define ssi_enable_rx_intr() ( SSI_CR0 |= SSI_CR0_RIE | SSI_CR0_REIE ) #define ssi_disable_rx_intr() ( SSI_CR0 &= ~(SSI_CR0_RIE | SSI_CR0_REIE) ) #define ssi_enable_txfifo_half_empty_intr() ( SSI_CR0 |= SSI_CR0_TIE ) #define ssi_disable_txfifo_half_empty_intr() ( SSI_CR0 &= ~SSI_CR0_TIE ) #define ssi_enable_tx_error_intr() ( SSI_CR0 |= SSI_CR0_TEIE ) #define ssi_disable_tx_error_intr() ( SSI_CR0 &= ~SSI_CR0_TEIE ) #define ssi_enable_rxfifo_half_full_intr() ( SSI_CR0 |= SSI_CR0_RIE ) #define ssi_disable_rxfifo_half_full_intr() ( SSI_CR0 &= ~SSI_CR0_RIE ) #define ssi_enable_rx_error_intr() ( SSI_CR0 |= SSI_CR0_REIE ) #define ssi_disable_rx_error_intr() ( SSI_CR0 &= ~SSI_CR0_REIE ) #define ssi_enable_loopback() ( SSI_CR0 |= SSI_CR0_LOOP ) #define ssi_disable_loopback() ( SSI_CR0 &= ~SSI_CR0_LOOP ) #define ssi_enable_receive() ( SSI_CR0 &= ~SSI_CR0_DISREV ) #define ssi_disable_receive() ( SSI_CR0 |= SSI_CR0_DISREV ) #define ssi_finish_receive() ( SSI_CR0 |= (SSI_CR0_RFINE | SSI_CR0_RFINC) ) #define ssi_disable_recvfinish() ( SSI_CR0 &= ~(SSI_CR0_RFINE | SSI_CR0_RFINC) ) #define ssi_flush_txfifo() ( SSI_CR0 |= SSI_CR0_TFLUSH ) #define ssi_flush_rxfifo() ( SSI_CR0 |= SSI_CR0_RFLUSH ) #define ssi_flush_fifo() ( SSI_CR0 |= SSI_CR0_TFLUSH | SSI_CR0_RFLUSH ) #define ssi_finish_transmit() ( SSI_CR1 &= ~SSI_CR1_UNFIN ) static void ssi_spi_format(): SSI_CR1 &= ~SSI_CR1_FMAT_MASK SSI_CR1 |= SSI_CR1_FMAT_SPI SSI_CR1 &= ~(SSI_CR1_TFVCK_MASK|SSI_CR1_TCKFI_MASK) SSI_CR1 |= (SSI_CR1_TFVCK_1 | SSI_CR1_TCKFI_1) // TI's SSP format, must clear SSI_CR1.UNFIN static void ssi_ssp_format (): SSI_CR1 &= ~(SSI_CR1_FMAT_MASK | SSI_CR1_UNFIN) SSI_CR1 |= SSI_CR1_FMAT_SSP // National's Microwire format, must clear SSI_CR0.RFINE, and set max delay static void ssi_microwire_format (): SSI_CR1 &= ~SSI_CR1_FMAT_MASK SSI_CR1 |= SSI_CR1_FMAT_MW1 SSI_CR1 &= ~(SSI_CR1_TFVCK_MASK|SSI_CR1_TCKFI_MASK) SSI_CR1 |= (SSI_CR1_TFVCK_3 | SSI_CR1_TCKFI_3) SSI_CR0 &= ~SSI_CR0_RFINE // CE# level (FRMHL), CE# in interval time (ITFRM), clock phase and polarity (PHA POL), interval time (SSIITR), interval characters/frame (SSIICR) // frmhl,endian,mcom,flen,pha,pol MASK #define SSICR1_MISC_MASK ( SSI_CR1_FRMHL_MASK | SSI_CR1_LFST | SSI_CR1_MCOM_MASK | SSI_CR1_FLEN_MASK | SSI_CR1_PHA | SSI_CR1_POL ) static void ssi_spi_set_misc (unsigned frmhl, unsigned endian, unsigned flen, unsigned mcom, unsigned pha, unsigned pol): SSI_CR1 &= ~SSICR1_MISC_MASK SSI_CR1 |= ((frmhl) << 30) | ((endian) << 25) | (((mcom) - 1) << 12) | (((flen) - 2) << 4) | ((pha) << 1) | (pol) // Transfer with MSB or LSB first #define ssi_set_msb() ( SSI_CR1 &= ~SSI_CR1_LFST ) #define ssi_set_lsb() ( SSI_CR1 |= SSI_CR1_LFST ) #define ssi_set_frame_length(n) SSI_CR1 = (SSI_CR1 & ~SSI_CR1_FLEN_MASK) | (((n) - 2) << 4) // n = 1 - 16 #define ssi_set_microwire_command_length(n) ( SSI_CR1 = ((SSI_CR1 & ~SSI_CR1_MCOM_MASK) | SSI_CR1_MCOM_##n##BIT) ) // Set the clock phase for SPI #define ssi_set_spi_clock_phase(n) ( SSI_CR1 = ((SSI_CR1 & ~SSI_CR1_PHA) | ((n&0x1)<< 1))) // Set the clock polarity for SPI #define ssi_set_spi_clock_polarity(n) ( SSI_CR1 = ((SSI_CR1 & ~SSI_CR1_POL) | (n&0x1)) ) // n = ix8 #define ssi_set_tx_trigger(n) do { SSI_CR1 &= ~SSI_CR1_TTRG_MASK; SSI_CR1 |= SSI_CR1_TTRG_##n; } while (0) // n = ix8 #define ssi_set_rx_trigger(n) do { SSI_CR1 &= ~SSI_CR1_RTRG_MASK; SSI_CR1 |= SSI_CR1_RTRG_##n; } while (0) #define ssi_get_txfifo_count() ( (SSI_SR & SSI_SR_TFIFONUM_MASK) >> SSI_SR_TFIFONUM_BIT ) #define ssi_get_rxfifo_count() ( (SSI_SR & SSI_SR_RFIFONUM_MASK) >> SSI_SR_RFIFONUM_BIT ) #define ssi_clear_errors() ( SSI_SR &= ~(SSI_SR_UNDR | SSI_SR_OVER) ) #define ssi_transfer_end() ( SSI_SR & SSI_SR_END ) #define ssi_is_busy() ( SSI_SR & SSI_SR_BUSY ) #define ssi_txfifo_full() ( SSI_SR & SSI_SR_TFF ) #define ssi_rxfifo_empty() ( SSI_SR & SSI_SR_RFE ) #define ssi_rxfifo_noempty() ( SSI_SR & SSI_SR_RFHF ) #define ssi_set_clk(dev_clk, ssi_clk) ( SSI_GR = (dev_clk) / (2*(ssi_clk)) - 1 ) #define ssi_receive_data() SSI_DR #define ssi_transmit_data(v) ( SSI_DR = (v) ) //************************************************************************** // CIM //************************************************************************** #define cim_enable() ( CIM_CTRL |= CIM_CTRL_ENA ) #define cim_disable() ( CIM_CTRL &= ~CIM_CTRL_ENA ) #define cim_input_data_inverse() ( CIM_CFG |= CIM_CFG_INV_DAT ) #define cim_input_data_normal() ( CIM_CFG &= ~CIM_CFG_INV_DAT ) #define cim_vsync_active_low() ( CIM_CFG |= CIM_CFG_VSP ) #define cim_vsync_active_high() ( CIM_CFG &= ~CIM_CFG_VSP ) #define cim_hsync_active_low() ( CIM_CFG |= CIM_CFG_HSP ) #define cim_hsync_active_high() ( CIM_CFG &= ~CIM_CFG_HSP ) #define cim_sample_data_at_pclk_falling_edge() ( CIM_CFG |= CIM_CFG_PCP ) #define cim_sample_data_at_pclk_rising_edge() ( CIM_CFG &= ~CIM_CFG_PCP ) #define cim_enable_dummy_zero() ( CIM_CFG |= CIM_CFG_DUMMY_ZERO ) #define cim_disable_dummy_zero() ( CIM_CFG &= ~CIM_CFG_DUMMY_ZERO ) #define cim_select_external_vsync() ( CIM_CFG |= CIM_CFG_EXT_VSYNC ) #define cim_select_internal_vsync() ( CIM_CFG &= ~CIM_CFG_EXT_VSYNC ) // n=0-7 #define cim_set_data_packing_mode(n) do { CIM_CFG &= ~CIM_CFG_PACK_MASK; CIM_CFG |= (CIM_CFG_PACK_##n); } while (0) static void cim_enable_ccir656_progressive_mode (): CIM_CFG &= ~CIM_CFG_DSM_MASK CIM_CFG |= CIM_CFG_DSM_CPM static void cim_enable_ccir656_interlace_mode (): CIM_CFG &= ~CIM_CFG_DSM_MASK CIM_CFG |= CIM_CFG_DSM_CIM static void cim_enable_gated_clock_mode (): CIM_CFG &= ~CIM_CFG_DSM_MASK CIM_CFG |= CIM_CFG_DSM_GCM static void cim_enable_nongated_clock_mode (): CIM_CFG &= ~CIM_CFG_DSM_MASK CIM_CFG |= CIM_CFG_DSM_NGCM // sclk:system bus clock // mclk: CIM master clock #define cim_set_master_clk(sclk, mclk) do { CIM_CTRL &= ~CIM_CTRL_MCLKDIV_MASK; CIM_CTRL |= (((sclk)/(mclk) - 1) << CIM_CTRL_MCLKDIV_BIT); } while (0) #define cim_enable_sof_intr() ( CIM_CTRL |= CIM_CTRL_DMA_SOFM ) #define cim_disable_sof_intr() ( CIM_CTRL &= ~CIM_CTRL_DMA_SOFM ) #define cim_enable_eof_intr() ( CIM_CTRL |= CIM_CTRL_DMA_EOFM ) #define cim_disable_eof_intr() ( CIM_CTRL &= ~CIM_CTRL_DMA_EOFM ) #define cim_enable_stop_intr() ( CIM_CTRL |= CIM_CTRL_DMA_STOPM ) #define cim_disable_stop_intr() ( CIM_CTRL &= ~CIM_CTRL_DMA_STOPM ) #define cim_enable_trig_intr() ( CIM_CTRL |= CIM_CTRL_RXF_TRIGM ) #define cim_disable_trig_intr() ( CIM_CTRL &= ~CIM_CTRL_RXF_TRIGM ) #define cim_enable_rxfifo_overflow_intr() ( CIM_CTRL |= CIM_CTRL_RXF_OFM ) #define cim_disable_rxfifo_overflow_intr() ( CIM_CTRL &= ~CIM_CTRL_RXF_OFM ) // n=1-16 #define cim_set_frame_rate(n) do { CIM_CTRL &= ~CIM_CTRL_FRC_MASK; CIM_CTRL |= CIM_CTRL_FRC_##n; } while (0) #define cim_enable_dma() ( CIM_CTRL |= CIM_CTRL_DMA_EN ) #define cim_disable_dma() ( CIM_CTRL &= ~CIM_CTRL_DMA_EN ) #define cim_reset_rxfifo() ( CIM_CTRL |= CIM_CTRL_RXF_RST ) #define cim_unreset_rxfifo() ( CIM_CTRL &= ~CIM_CTRL_RXF_RST ) // n=4,8,12,16,20,24,28,32 #define cim_set_rxfifo_trigger(n) do { CIM_CTRL &= ~CIM_CTRL_RXF_TRIG_MASK; CIM_CTRL |= CIM_CTRL_RXF_TRIG_##n; } while (0) #define cim_clear_state() ( CIM_STATE = 0 ) #define cim_disable_done() ( CIM_STATE & CIM_STATE_VDD ) #define cim_rxfifo_empty() ( CIM_STATE & CIM_STATE_RXF_EMPTY ) #define cim_rxfifo_reach_trigger() ( CIM_STATE & CIM_STATE_RXF_TRIG ) #define cim_rxfifo_overflow() ( CIM_STATE & CIM_STATE_RXF_OF ) #define cim_clear_rxfifo_overflow() ( CIM_STATE &= ~CIM_STATE_RXF_OF ) #define cim_dma_stop() ( CIM_STATE & CIM_STATE_DMA_STOP ) #define cim_dma_eof() ( CIM_STATE & CIM_STATE_DMA_EOF ) #define cim_dma_sof() ( CIM_STATE & CIM_STATE_DMA_SOF ) #define cim_get_iid() ( CIM_IID ) #define cim_get_image_data() ( CIM_RXFIFO ) #define cim_get_dam_cmd() ( CIM_CMD ) #define cim_set_da(a) ( CIM_DA = (a) ) //************************************************************************** // LCD //************************************************************************** #define lcd_as_smart_lcd() ( LCD_CFG |= (1<> LCD_VSYNC_VPS_BIT ) #define lcd_vsync_get_vpe() ( (LCD_VSYNC & LCD_VSYNC_VPE_MASK) >> LCD_VSYNC_VPE_BIT ) #define lcd_vsync_set_vpe(n) do { LCD_VSYNC &= ~LCD_VSYNC_VPE_MASK; LCD_VSYNC |= (n) << LCD_VSYNC_VPE_BIT; } while (0) #define lcd_hsync_get_hps() ( (LCD_HSYNC & LCD_HSYNC_HPS_MASK) >> LCD_HSYNC_HPS_BIT ) #define lcd_hsync_set_hps(n) do { LCD_HSYNC &= ~LCD_HSYNC_HPS_MASK; LCD_HSYNC |= (n) << LCD_HSYNC_HPS_BIT; } while (0) #define lcd_hsync_get_hpe() ( (LCD_HSYNC & LCD_HSYNC_HPE_MASK) >> LCD_VSYNC_HPE_BIT ) #define lcd_hsync_set_hpe(n) do { LCD_HSYNC &= ~LCD_HSYNC_HPE_MASK; LCD_HSYNC |= (n) << LCD_HSYNC_HPE_BIT; } while (0) #define lcd_vat_get_ht() ( (LCD_VAT & LCD_VAT_HT_MASK) >> LCD_VAT_HT_BIT ) #define lcd_vat_set_ht(n) do { LCD_VAT &= ~LCD_VAT_HT_MASK; LCD_VAT |= (n) << LCD_VAT_HT_BIT; } while (0) #define lcd_vat_get_vt() ( (LCD_VAT & LCD_VAT_VT_MASK) >> LCD_VAT_VT_BIT ) #define lcd_vat_set_vt(n) do { LCD_VAT &= ~LCD_VAT_VT_MASK; LCD_VAT |= (n) << LCD_VAT_VT_BIT; } while (0) #define lcd_dah_get_hds() ( (LCD_DAH & LCD_DAH_HDS_MASK) >> LCD_DAH_HDS_BIT ) #define lcd_dah_set_hds(n) do { LCD_DAH &= ~LCD_DAH_HDS_MASK; LCD_DAH |= (n) << LCD_DAH_HDS_BIT; } while (0) #define lcd_dah_get_hde() ( (LCD_DAH & LCD_DAH_HDE_MASK) >> LCD_DAH_HDE_BIT ) #define lcd_dah_set_hde(n) do { LCD_DAH &= ~LCD_DAH_HDE_MASK; LCD_DAH |= (n) << LCD_DAH_HDE_BIT; } while (0) #define lcd_dav_get_vds() ( (LCD_DAV & LCD_DAV_VDS_MASK) >> LCD_DAV_VDS_BIT ) #define lcd_dav_set_vds(n) do { LCD_DAV &= ~LCD_DAV_VDS_MASK; LCD_DAV |= (n) << LCD_DAV_VDS_BIT; } while (0) #define lcd_dav_get_vde() ( (LCD_DAV & LCD_DAV_VDE_MASK) >> LCD_DAV_VDE_BIT ) #define lcd_dav_set_vde(n) do { LCD_DAV &= ~LCD_DAV_VDE_MASK; LCD_DAV |= (n) << LCD_DAV_VDE_BIT; } while (0) #define lcd_cmd0_set_sofint() ( LCD_CMD0 |= LCD_CMD_SOFINT ) #define lcd_cmd0_clr_sofint() ( LCD_CMD0 &= ~LCD_CMD_SOFINT ) #define lcd_cmd1_set_sofint() ( LCD_CMD1 |= LCD_CMD_SOFINT ) #define lcd_cmd1_clr_sofint() ( LCD_CMD1 &= ~LCD_CMD_SOFINT ) #define lcd_cmd0_set_eofint() ( LCD_CMD0 |= LCD_CMD_EOFINT ) #define lcd_cmd0_clr_eofint() ( LCD_CMD0 &= ~LCD_CMD_EOFINT ) #define lcd_cmd1_set_eofint() ( LCD_CMD1 |= LCD_CMD_EOFINT ) #define lcd_cmd1_clr_eofint() ( LCD_CMD1 &= ~LCD_CMD_EOFINT ) #define lcd_cmd0_set_pal() ( LCD_CMD0 |= LCD_CMD_PAL ) #define lcd_cmd0_clr_pal() ( LCD_CMD0 &= ~LCD_CMD_PAL ) #define lcd_cmd0_get_len() ( (LCD_CMD0 & LCD_CMD_LEN_MASK) >> LCD_CMD_LEN_BIT ) #define lcd_cmd1_get_len() ( (LCD_CMD1 & LCD_CMD_LEN_MASK) >> LCD_CMD_LEN_BIT ) //************************************************************************** // RTC ops //************************************************************************** #define rtc_write_ready() ( (RTC_RCR & RTC_RCR_WRDY) >> RTC_RCR_WRDY_BIT ) #define rtc_enabled() ( RTC_RCR |= RTC_RCR_RTCE ) #define rtc_disabled() ( RTC_RCR &= ~RTC_RCR_RTCE ) #define rtc_enable_alarm() ( RTC_RCR |= RTC_RCR_AE ) #define rtc_disable_alarm() ( RTC_RCR &= ~RTC_RCR_AE ) #define rtc_alarm_is_enabled() ( RTC_RCR & RTC_RCR_AE ) #define rtc_enable_alarm_irq() ( RTC_RCR |= RTC_RCR_AIE ) #define rtc_disable_alarm_irq() ( RTC_RCR &= ~RTC_RCR_AIE ) #define rtc_enable_1Hz_irq() ( RTC_RCR |= RTC_RCR_1HZIE ) #define rtc_disable_1Hz_irq() ( RTC_RCR &= ~RTC_RCR_1HZIE ) #define rtc_get_1Hz_flag() ( (RTC_RCR >> RTC_RCR_1HZ_BIT) & 0x1 ) #define rtc_clear_1Hz_flag() ( RTC_RCR &= ~RTC_RCR_1HZ ) #define rtc_get_alarm_flag() ( (RTC_RCR >> RTC_RCR_AF_BIT) & 0x1 ) #define rtc_clear_alarm_flag() ( RTC_RCR &= ~RTC_RCR_AF ) #define rtc_get_second() ( RTC_RSR ) #define rtc_set_second(v) ( RTC_RSR = v ) #define rtc_get_alarm_second() ( RTC_RSAR ) #define rtc_set_alarm_second(v) ( RTC_RSAR = v ) #define rtc_RGR_is_locked() ( (RTC_RGR >> RTC_RGR_LOCK) ) #define rtc_lock_RGR() ( RTC_RGR |= RTC_RGR_LOCK ) #define rtc_unlock_RGR() ( RTC_RGR &= ~RTC_RGR_LOCK ) #define rtc_get_adjc_val() ( (RTC_RGR & RTC_RGR_ADJC_MASK) >> RTC_RGR_ADJC_BIT ) #define rtc_set_adjc_val(v) ( RTC_RGR = ( (RTC_RGR & ~RTC_RGR_ADJC_MASK) | (v << RTC_RGR_ADJC_BIT) )) #define rtc_get_nc1Hz_val() ( (RTC_RGR & RTC_RGR_NC1HZ_MASK) >> RTC_RGR_NC1HZ_BIT ) #define rtc_set_nc1Hz_val(v) ( RTC_RGR = ( (RTC_RGR & ~RTC_RGR_NC1HZ_MASK) | (v << RTC_RGR_NC1HZ_BIT) )) #define rtc_power_down() ( RTC_HCR |= RTC_HCR_PD ) #define rtc_get_hwfcr_val() ( RTC_HWFCR & RTC_HWFCR_MASK ) #define rtc_set_hwfcr_val(v) ( RTC_HWFCR = (v) & RTC_HWFCR_MASK ) #define rtc_get_hrcr_val() ( RTC_HRCR & RTC_HRCR_MASK ) #define rtc_set_hrcr_val(v) ( RTC_HRCR = (v) & RTC_HRCR_MASK ) #define rtc_enable_alarm_wakeup() ( RTC_HWCR |= RTC_HWCR_EALM ) #define rtc_disable_alarm_wakeup() ( RTC_HWCR &= ~RTC_HWCR_EALM ) #define rtc_status_hib_reset_occur() ( (RTC_HWRSR >> RTC_HWRSR_HR) & 0x1 ) #define rtc_status_ppr_reset_occur() ( (RTC_HWRSR >> RTC_HWRSR_PPR) & 0x1 ) #define rtc_status_wakeup_pin_waken_up() ( (RTC_HWRSR >> RTC_HWRSR_PIN) & 0x1 ) #define rtc_status_alarm_waken_up() ( (RTC_HWRSR >> RTC_HWRSR_ALM) & 0x1 ) #define rtc_clear_hib_stat_all() ( RTC_HWRSR = 0 ) #define rtc_get_scratch_pattern() (RTC_HSPR) #define rtc_set_scratch_pattern(n) (RTC_HSPR = n ) #ifdef __KERNEL__ static void setup_sdram (): // SDRAM BANK Number: 1, 2 unsigned CONFIG_NR_DRAM_BANKS = 1 // CAS latency: 2 or 3 unsigned SDRAM_CASL = 2 // SDRAM Timings, unit: ns // RAS# Active Time unsigned SDRAM_TRAS = 45 // RAS# to CAS# Delay unsigned SDRAM_RCD = 20 // RAS# Precharge Time unsigned SDRAM_TPC = 20 // Write Latency Time unsigned SDRAM_TRWL = 7 // Refresh period: 4096 refresh cycles/64ms unsigned SDRAM_TREF = 7812 unsigned dmcr0, dmcr, sdmode, tmp, cpu_clk, mem_clk, ns unsigned cas_latency_sdmr[2] = { EMC_SDMR_CAS_2, EMC_SDMR_CAS_3 } unsigned cas_latency_dmcr[2] = { 1 << EMC_DMCR_TCL_BIT, 2 << EMC_DMCR_TCL_BIT } int div[] = {1, 2, 3, 4, 6, 8, 12, 16, 24, 32} cpu_clk = 252000000 gpio_as_sdram_16bit () unsigned SDRAM_BW16 = 0 unsigned SDRAM_BANK4 = 1 unsigned SDRAM_ROW = 12 unsigned SDRAM_COL = 8 mem_clk = cpu_clk * div[cpm_get_cdiv()] / div[cpm_get_mdiv()] EMC_BCR = 0 EMC_RTCSR = 0 unsigned SDRAM_ROW0 = 11 unsigned SDRAM_COL0 = 8 unsigned SDRAM_BANK40 = 0 dmcr0 = ((SDRAM_ROW0-11)< 11: tmp = 11 dmcr |= ((tmp-4) << EMC_DMCR_TRAS_BIT) tmp = SDRAM_RCD/ns if tmp > 3: tmp = 3 dmcr |= (tmp << EMC_DMCR_RCD_BIT) tmp = SDRAM_TPC/ns if tmp > 7: tmp = 7 dmcr |= (tmp << EMC_DMCR_TPC_BIT) tmp = SDRAM_TRWL/ns if tmp > 3: tmp = 3 dmcr |= (tmp << EMC_DMCR_TRWL_BIT) tmp = (SDRAM_TRAS + SDRAM_TPC)/ns if tmp > 14: tmp = 14 dmcr |= (((tmp + 1) >> 1) << EMC_DMCR_TRC_BIT) // SDRAM mode value sdmode = EMC_SDMR_BT_SEQ | EMC_SDMR_OM_NORMAL | EMC_SDMR_BL_4 | cas_latency_sdmr[((SDRAM_CASL == 3) ? 1 : 0)]; // Stage 1. Precharge all banks by writing SDMR with DMCR.MRSET=0 EMC_DMCR = dmcr REG8(EMC_SDMR0|sdmode) = 0 // Wait for precharge, > 200us tmp = (cpu_clk / 1000000) * 1000 volatile unsigned t = tmp while t--: // Stage 2. Enable auto-refresh EMC_DMCR = dmcr | EMC_DMCR_RFSH tmp = SDRAM_TREF/ns tmp = tmp/64 + 1 if tmp > 0xff: tmp = 0xff EMC_RTCOR = tmp EMC_RTCNT = 0 // Divisor is 64, CKO/64 EMC_RTCSR = EMC_RTCSR_CKS_64 // Wait for number of auto-refresh cycles tmp = (cpu_clk / 1000000) * 1000 t = tmp while t--: // Stage 3. Mode Register Set EMC_DMCR = dmcr0 | EMC_DMCR_RFSH | EMC_DMCR_MRSET REG8(EMC_SDMR0|sdmode) = 0 // Set back to basic DMCR value EMC_DMCR = dmcr | EMC_DMCR_RFSH | EMC_DMCR_MRSET #if 0 EMC_SMCR (0) = 0x00000080 EMC_SMCR (1) = 0x094c4400 EMC_SMCR (2) = 0x0fff7700 EMC_SMCR (3) = 0x0fff7700 EMC_SMCR (4) = 0x0fff7700 EMC_SACR (0) = 0x1cfc EMC_SACR (1) = 0x18fc EMC_SACR (2) = 0x14fc EMC_SACR (3) = 0x0cfc EMC_SACR (4) = 0x08fc EMC_DMCR = 0x85aa3211 EMC_RTCSR = 0x83 EMC_RTCOR = 0x1f #endif #if 0 for unsigned i = 0; i < 5; ++i: dbg_log ("memory: ") dbg_log_num (EMC_SMCR (i), 8) dbg_log (",") dbg_log_num (EMC_SACR (i), 8) dbg_log (";") dbg_log_num (EMC_RTCSR, 8) dbg_log (",") dbg_log_num (EMC_RTCOR, 8) dbg_log ("\n") #endif static void setup_uart (): #ifndef NDEBUG // Set up uart. cpm_start_uart0 () gpio_as_uart0 () UART0_IER = 0 UART0_FCR = 0 UART0_MCR = 0 UART0_SIRCR = 0 UART0_UACR = 0 UART0_UMR = 16 UART0_LCR = UARTLCR_WLEN_8 | UARTLCR_STOP1 | UARTLCR_DLAB unsigned const baud = 57600 unsigned uart_div = 12000000 / 16 / baud UART0_DLHR = (uart_div >> 8) & 0xff UART0_DLLR = uart_div & 0xff UART0_LCR = UARTLCR_WLEN_8 | UARTLCR_STOP1 UART0_FCR = UARTFCR_UUE | UARTFCR_FE | UARTFCR_RFLS | UARTFCR_TFLS #endif #endif #endif