/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2011 by Tomasz Moń * Copyright (C) 2007 by Karl Kurbjun * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "cpu.h" #include "mmu-arm.h" #include "kernel.h" #include "system.h" #include "panic.h" #include "uart-target.h" #include "system-arm.h" #include "spi.h" #include "i2c.h" #ifdef CREATIVE_ZVx #include "dma-target.h" #endif #ifdef MROBE_500 #include "usb-mr500.h" #endif #ifdef SANSA_CONNECT #include "avr-sansaconnect.h" #endif static unsigned short clock_arm_slow = 0xFFFF; static unsigned short clock_arm_fast = 0xFFFF; #define default_interrupt(name) \ extern __attribute__((weak,alias("UIRQ"))) void name (void) void irq_handler(void) __attribute__((interrupt ("IRQ"), section(".icode"))); void fiq_handler(void) __attribute__((interrupt ("FIQ"), section(".icode"))); default_interrupt(TIMER0); default_interrupt(TIMER1); default_interrupt(TIMER2); default_interrupt(TIMER3); default_interrupt(CCD_VD0); default_interrupt(CCD_VD1); default_interrupt(CCD_WEN); default_interrupt(VENC); default_interrupt(SERIAL0); default_interrupt(SERIAL1); default_interrupt(EXT_HOST); default_interrupt(DSPHINT); default_interrupt(UART0); default_interrupt(UART1); default_interrupt(USB_DMA); default_interrupt(USB_CORE); default_interrupt(VLYNQ); default_interrupt(MTC0); default_interrupt(MTC1); default_interrupt(SD_MMC); default_interrupt(SDIO_MS); default_interrupt(GIO0); default_interrupt(GIO1); default_interrupt(GIO2); default_interrupt(GIO3); default_interrupt(GIO4); default_interrupt(GIO5); default_interrupt(GIO6); default_interrupt(GIO7); default_interrupt(GIO8); default_interrupt(GIO9); default_interrupt(GIO10); default_interrupt(GIO11); default_interrupt(GIO12); default_interrupt(GIO13); default_interrupt(GIO14); default_interrupt(GIO15); default_interrupt(PREVIEW0); default_interrupt(PREVIEW1); default_interrupt(WATCHDOG); default_interrupt(I2C); default_interrupt(CLKC); default_interrupt(ICE); default_interrupt(ARMCOM_RX); default_interrupt(ARMCOM_TX); default_interrupt(RESERVED); /* The entry address is equal to base address plus an offset. * The offset is based on the priority of the interrupt. So if * the priority of an interrupt is changed, the user should also * change the offset for the interrupt in the entry table. */ static const unsigned short const irqpriority[] = { IRQ_TIMER0,IRQ_TIMER1,IRQ_TIMER2,IRQ_TIMER3,IRQ_CCD_VD0,IRQ_CCD_VD1, IRQ_CCD_WEN,IRQ_VENC,IRQ_SERIAL0,IRQ_SERIAL1,IRQ_EXT_HOST,IRQ_DSPHINT, IRQ_UART0,IRQ_UART1,IRQ_USB_DMA,IRQ_USB_CORE,IRQ_VLYNQ,IRQ_MTC0,IRQ_MTC1, IRQ_SD_MMC,IRQ_SDIO_MS,IRQ_GIO0,IRQ_GIO1,IRQ_GIO2,IRQ_GIO3,IRQ_GIO4,IRQ_GIO5, IRQ_GIO6,IRQ_GIO7,IRQ_GIO8,IRQ_GIO9,IRQ_GIO10,IRQ_GIO11,IRQ_GIO12,IRQ_GIO13, IRQ_GIO14,IRQ_GIO15,IRQ_PREVIEW0,IRQ_PREVIEW1,IRQ_WATCHDOG,IRQ_I2C,IRQ_CLKC, IRQ_ICE,IRQ_ARMCOM_RX,IRQ_ARMCOM_TX,IRQ_RESERVED }; /* IRQ priorities, ranging from highest to lowest */ static void (* const irqvector[])(void) __attribute__ ((section(".idata"))) = { TIMER0,TIMER1,TIMER2,TIMER3,CCD_VD0,CCD_VD1, CCD_WEN,VENC,SERIAL0,SERIAL1,EXT_HOST,DSPHINT, UART0,UART1,USB_DMA,USB_CORE,VLYNQ,MTC0,MTC1, SD_MMC,SDIO_MS,GIO0,GIO1,GIO2,GIO3,GIO4,GIO5, GIO6,GIO7,GIO8,GIO9,GIO10,GIO11,GIO12,GIO13, GIO14,GIO15,PREVIEW0,PREVIEW1,WATCHDOG,I2C,CLKC, ICE,ARMCOM_RX,ARMCOM_TX,RESERVED }; static const char * const irqname[] = { "TIMER0","TIMER1","TIMER2","TIMER3","CCD_VD0","CCD_VD1", "CCD_WEN","VENC","SERIAL0","SERIAL1","EXT_HOST","DSPHINT", "UART0","UART1","USB_DMA","USB_CORE","VLYNQ","MTC0","MTC1", "SD_MMC","SDIO_MS","GIO0","GIO1","GIO2","GIO3","GIO4","GIO5", "GIO6","GIO7","GIO8","GIO9","GIO10","GIO11","GIO12","GIO13", "GIO14","GIO15","PREVIEW0","PREVIEW1","WATCHDOG","I2C","CLKC", "ICE","ARMCOM_RX","ARMCOM_TX","RESERVED" }; static void UIRQ(void) { unsigned int offset = (IO_INTC_IRQENTRY0>>2)-1; panicf("Unhandled IRQ %02X: %s", offset, irqname[offset]); } void irq_handler(void) { unsigned short addr = IO_INTC_IRQENTRY0>>2; if(addr != 0) { addr--; irqvector[addr](); } } void fiq_handler(void) { /* * Based on: linux/arch/arm/kernel/entry-armv.S and system-meg-fx.c */ unsigned short addr = IO_INTC_FIQENTRY0>>2; if(addr != 0) { addr--; irqvector[addr](); } } void system_reboot(void) { /* Code taken from linux/include/asm-arm/arch-itdm320-20/system.h at NeuroSVN */ __asm__ __volatile__( "mov ip, #0 \n" "mcr p15, 0, ip, c7, c7, 0 @ invalidate cache \n" "mcr p15, 0, ip, c7, c10,4 @ drain WB \n" "mcr p15, 0, ip, c8, c7, 0 @ flush TLB (v4) \n" "mrc p15, 0, ip, c1, c0, 0 @ get ctrl register\n" "bic ip, ip, #0x000f @ ............wcam \n" "bic ip, ip, #0x2100 @ ..v....s........ \n" "mcr p15, 0, ip, c1, c0, 0 @ ctrl register \n" "mov ip, #0xFF000000 \n" "orr pc, ip, #0xFF0000 @ ip = 0xFFFF0000 \n" : : : "cc" ); } void system_exception_wait(void) { /* Mask all Interrupts. */ IO_INTC_EINT0 = 0; IO_INTC_EINT1 = 0; IO_INTC_EINT2 = 0; #ifdef MROBE_500 while ((IO_GIO_BITSET0&0x01) != 0); /* Wait for power button */ #endif #ifdef SANSA_CONNECT while (1); /* Holding power button for a while makes avr system reset */ #endif } void system_init(void) { // unsigned int vector_addr; /* Pin 33 is connected to a buzzer, for an annoying sound set * PWM0C == 0x3264 * PWM0H == 0x1932 * Function to 1 * Since this is not used in the FW, set it to a normal output at a zero * level. */ /* taken from linux/arch/arm/mach-itdm320-20/irq.c */ /* Clearing all FIQs and IRQs. */ IO_INTC_IRQ0 = 0xFFFF; IO_INTC_IRQ1 = 0xFFFF; IO_INTC_IRQ2 = 0xFFFF; IO_INTC_FIQ0 = 0xFFFF; IO_INTC_FIQ1 = 0xFFFF; IO_INTC_FIQ2 = 0xFFFF; /* Masking all Interrupts. */ IO_INTC_EINT0 = 0; IO_INTC_EINT1 = 0; IO_INTC_EINT2 = 0; /* Setting INTC to all IRQs. */ IO_INTC_FISEL0 = 0; IO_INTC_FISEL1 = 0; IO_INTC_FISEL2 = 0; /* Only initially needed clocks should be turned on */ IO_CLK_MOD0 = CLK_MOD0_HPIB | CLK_MOD0_DSP | CLK_MOD0_SDRAMC | CLK_MOD0_EMIF | CLK_MOD0_INTC | CLK_MOD0_AIM | CLK_MOD0_AHB | CLK_MOD0_BUSC | CLK_MOD0_ARM; IO_CLK_MOD1 = CLK_MOD1_CPBUS; IO_CLK_MOD2 = CLK_MOD2_GIO; #if 0 if (IO_BUSC_REVR == REVR_ES11) { /* Agressive clock setup for newer parts (ES11) - this is actually lower * power also. */ /* Setup the EMIF interface timings */ /* ATA interface: * If this is the newer silicon the timings need to be slowed down some * for reliable access due to the faster ARM clock. */ /* OE width, WE width, CS width, Cycle width */ IO_EMIF_CS3CTRL1 = (8 << 12) | (8 << 8) | (14 << 4) | 15; /* 14: Width (16), 12: Idles, 8: OE setup, 4: WE Setup, CS setup */ IO_EMIF_CS3CTRL2 = (1<<14) | (1 << 12) | (3 << 8) | (3 << 4) | 1; /* USB interface: * The following EMIF timing values are from the OF: * IO_EMIF_CS4CTRL1 = 0x66AB; * IO_EMIF_CS4CTRL2 = 0x4220; * * More agressive numbers may be possible, but it depends on the clocking * setup. */ IO_EMIF_CS4CTRL1 = 0x66AB; IO_EMIF_CS4CTRL2 = 0x4220; /* 27 MHz input clock: * PLLA: 27 * 15 / 2 = 202.5 MHz * PLLB: 27 * 9 / 2 = 121.5 MHz (off: bit 12) */ IO_CLK_PLLA = (14 << 4) | 1; IO_CLK_PLLB = ( 1 << 12) | ( 8 << 4) | 1; /* Set the slow and fast clock speeds used for boosting * Slow Setup: * ARM div = 4 ( 50.625 MHz ) * AHB div = 1 ( 50.625 MHz ) * Fast Setup: * ARM div = 1 ( 202.5 MHz ) * AHB div = 2 ( 101.25 MHz ) */ clock_arm_slow = (0 << 8) | 3; clock_arm_fast = (1 << 8) | 0; IO_CLK_DIV0 = clock_arm_slow; /* SDRAM div= 2 ( 101.25 MHz ) * AXL div = 1 ( 202.5 MHz ) */ IO_CLK_DIV1 = (0 << 8) | 1; /* MS div = 15 ( 13.5 MHz ) * DSP div = 4 ( 50.625 MHz - could be double, but this saves power) */ IO_CLK_DIV2 = (3 << 8) | 14; /* MMC div = 256 ( slow ) * VENC div = 32 ( 843.75 KHz ) */ IO_CLK_DIV3 = (31 << 8) | 255; /* I2C div = 1 ( 48 MHz if M48XI is running ) * VLNQ div = 32 */ IO_CLK_DIV4 = (31 << 8) | 0; /* Feed everything from PLLA */ IO_CLK_SEL0=0x007E; IO_CLK_SEL1=0x1000; IO_CLK_SEL2=0x0000; } else #endif { #ifdef SANSA_CONNECT /* Setting AHB divisor to 0 increases power consumption */ clock_arm_slow = (1 << 8) | 3; clock_arm_fast = (1 << 8) | 1; #else /* Set the slow and fast clock speeds used for boosting * Slow Setup: * ARM div = 4 ( 87.5 MHz ) * AHB div = 1 ( 87.5 MHz ) * Fast Setup: * ARM div = 2 ( 175 MHz ) * AHB div = 2 ( 87.5 MHz ) */ clock_arm_slow = (0 << 8) | 3; clock_arm_fast = (1 << 8) | 1; #endif } /* M48XI disabled, USB buffer powerdown */ IO_CLK_LPCTL1 = 0x11; /* I2C wodn't work with this disabled */ /* IRQENTRY only reflects enabled interrupts */ IO_INTC_RAW = 0; // vector_addr = (unsigned int) irqvector; IO_INTC_ENTRY_TBA0 = 0;//(short) vector_addr & ~0x000F; IO_INTC_ENTRY_TBA1 = 0;//(short) (vector_addr >> 16); int i; /* Set interrupt priorities to predefined values */ for(i = 0; i < 23; i++) DM320_REG(0x0540+i*2) = ((irqpriority[i*2+1] & 0x3F) << 8) | (irqpriority[i*2] & 0x3F); /* IO_INTC_PRIORITYx */ /* Turn off all timers */ IO_TIMER0_TMMD = CONFIG_TIMER0_TMMD_STOP; IO_TIMER1_TMMD = CONFIG_TIMER1_TMMD_STOP; IO_TIMER2_TMMD = CONFIG_TIMER2_TMMD_STOP; IO_TIMER3_TMMD = CONFIG_TIMER3_TMMD_STOP; #ifndef SANSA_CONNECT /* UART1 is not used on Sansa Connect - don't power it up */ uart_init(); #endif spi_init(); #ifdef MROBE_500 /* Initialization is done so shut the front LED off so that the battery * can charge. */ IO_GIO_BITCLR2 = 0x0001; #endif #ifdef CREATIVE_ZVx dma_init(); #endif #ifdef SANSA_CONNECT /* keep WIFI CS and reset high to save power */ IO_GIO_DIR0 &= ~((1 << 4) /* CS */ | (1 << 3) /* reset */); IO_GIO_BITSET0 = (1 << 4) | (1 << 3); i2c_init(); avr_hid_init(); #ifndef BOOTLOADER /* Disable External Memory interface (used for accessing NOR flash) */ bitclr16(&IO_CLK_MOD0, CLK_MOD0_EMIF); #endif /* Unknown GIOs - set them to save power */ /* GIO40 - output 0 * GIO28 - output 0 */ IO_GIO_DIR2 &= ~(1 << 8); IO_GIO_BITCLR2 = (1 << 8); IO_GIO_DIR1 &= ~(1 << 12); IO_GIO_BITCLR1 = (1 << 12); #endif } int system_memory_guard(int newmode) { (void)newmode; return 0; } #ifdef HAVE_ADJUSTABLE_CPU_FREQ void set_cpu_frequency(long frequency) { /* If these variables have not been changed since startup then boosting * should not be used. */ if(clock_arm_slow == 0xFFFF || clock_arm_fast == 0xFFFF) { return; } if (frequency == CPUFREQ_MAX) { IO_CLK_DIV0 = clock_arm_fast; FREQ = CPUFREQ_MAX; } else { IO_CLK_DIV0 = clock_arm_slow; FREQ = CPUFREQ_NORMAL; } } #endif /* * Waits for specified amount of microseconds (or longer, but NEVER less) * * Maximum supported usec value is 10000, use sleep() for longer delays. */ void udelay(int usec) { /* * count and prev_tick must be initialized as soon as posible (right * after function entry) * * count must be initialized before prev_count */ unsigned short count = IO_TIMER1_TMCNT; long prev_tick = current_tick; /* initialization time/sequence of these values is not critical */ unsigned short stop; unsigned short tmp = IO_TIMER1_TMDIV; if (!irq_enabled()) { /* * Interrupts are disabled * * Clear TIMER1 interrupt to prevent returning from this fuction * before specified amount of time has passed * In worst case this makes udelay() take one tick longer */ IO_INTC_IRQ0 = INTR_IRQ0_TMR1; } /* * On Sansa Connect tick timer counts from 0 to 26999 * in this case stop will overflow only if usec > 10000 * such long delays shouldn't be blocking (use sleep() instead) */ stop = count + usec*((tmp+1)/10000); stop += (unsigned short)(((unsigned long)(usec)*((tmp%10000)+1))/10000); /* stop values over TMDIV won't ever be reached */ if (stop > tmp) { stop -= tmp; } /* * Status in IO_INTC_IRQ0 is changed even when interrupts are * masked. If bit 1 in IO_INTC_IRQ0 is set to 0, then * there is pending current_tick update. * * Relaying solely on current_tick value when interrupts are disabled * can lead to lockup. * Interrupt status bit check below is used to prevent this lockup. */ if (stop < count) { /* udelay will end after counter reset (tick) */ while ((IO_TIMER1_TMCNT < stop) || ((current_tick == prev_tick) /* ensure new tick */ && (IO_INTC_IRQ0 & INTR_IRQ0_TMR1))); /* prevent lock */ } else { /* udelay will end before counter reset (tick) */ while ((IO_TIMER1_TMCNT < stop) && ((current_tick == prev_tick) && (IO_INTC_IRQ0 & INTR_IRQ0_TMR1))); } } void mdelay(int msec) { int ms_per_tick = 1000 / HZ; /* Round up to next full tick */ sleep((msec + ms_per_tick - 1) / ms_per_tick); } #ifdef BOOTLOADER void system_prepare_fw_start(void) { tick_stop(); IO_INTC_EINT0 = 0; IO_INTC_EINT1 = 0; IO_INTC_EINT2 = 0; } #endif