Merge branch 'master' of git://git.denx.de/u-boot-arm

[karo-tx-uboot.git] / cpu / blackfin / start.S

/*
 * U-boot - start.S Startup file for Blackfin u-boot
 *
 * Copyright (c) 2005-2008 Analog Devices Inc.
 *
 * This file is based on head.S
 * Copyright (c) 2003  Metrowerks/Motorola
 * Copyright (C) 1998  D. Jeff Dionne <jeff@ryeham.ee.ryerson.ca>,
 *                     Kenneth Albanowski <kjahds@kjahds.com>,
 *                     The Silver Hammer Group, Ltd.
 * (c) 1995, Dionne & Associates
 * (c) 1995, DKG Display Tech.
 *
 * See file CREDITS for list of people who contributed to this
 * project.
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License as
 * published by the Free Software Foundation; either version 2 of
 * the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston,
 * MA 02110-1301 USA
 */

#include <config.h>
#include <asm/blackfin.h>
#include <asm/mach-common/bits/core.h>
#include <asm/mach-common/bits/dma.h>
#include <asm/mach-common/bits/pll.h>

#include "serial.h"

/* It may seem odd that we make calls to functions even though we haven't
 * relocated ourselves yet out of {flash,ram,wherever}.  This is OK because
 * the "call" instruction in the Blackfin architecture is actually PC
 * relative.  So we can call functions all we want and not worry about them
 * not being relocated yet.
 */

.text
ENTRY(_start)

        /* Set our initial stack to L1 scratch space */
        sp.l = LO(L1_SRAM_SCRATCH_END - 20);
        sp.h = HI(L1_SRAM_SCRATCH_END - 20);

#ifdef CONFIG_HW_WATCHDOG
# ifndef CONFIG_HW_WATCHDOG_TIMEOUT_START
#  define CONFIG_HW_WATCHDOG_TIMEOUT_START 5000
# endif
        /* Program the watchdog with an initial timeout of ~5 seconds.
         * That should be long enough to bootstrap ourselves up and
         * then the common u-boot code can take over.
         */
        P0.L = LO(WDOG_CNT);
        P0.H = HI(WDOG_CNT);
        R0.L = 0;
        R0.H = HI(MSEC_TO_SCLK(CONFIG_HW_WATCHDOG_TIMEOUT_START));
        [P0] = R0;
        /* fire up the watchdog - R0.L above needs to be 0x0000 */
        W[P0 + (WDOG_CTL - WDOG_CNT)] = R0;
#endif

        /* Turn on the serial for debugging the init process */
        serial_early_init
        serial_early_set_baud

        serial_early_puts("Init Registers");

        /* Disable self-nested interrupts and enable CYCLES for udelay() */
        R0 = CCEN | 0x30;
        SYSCFG = R0;

        /* Zero out registers required by Blackfin ABI.
         * http://docs.blackfin.uclinux.org/doku.php?id=application_binary_interface
         */
        r1 = 0 (x);
        /* Disable circular buffers */
        l0 = r1;
        l1 = r1;
        l2 = r1;
        l3 = r1;
        /* Disable hardware loops in case we were started by 'go' */
        lc0 = r1;
        lc1 = r1;

        /* Save RETX so we can pass it while booting Linux */
        r7 = RETX;

        /* Figure out where we are currently executing so that we can decide
         * how to best reprogram and relocate things.  We'll pass below:
         *  R4: load address of _start
         *  R5: current (not load) address of _start
         */
        serial_early_puts("Find ourselves");

        call _get_pc;
.Loffset:
        r1.l = .Loffset;
        r1.h = .Loffset;
        r4.l = _start;
        r4.h = _start;
        r3 = r1 - r4;
        r5 = r0 - r3;

        /* Inform upper layers if we had to do the relocation ourselves.
         * This allows us to detect whether we were loaded by 'go 0x1000'
         * or by the bootrom from an LDR.  "R6" is "loaded_from_ldr".
         */
        r6 = 1 (x);
        cc = r4 == r5;
        if cc jump .Lnorelocate;
        r6 = 0 (x);

        /* In bypass mode, we don't have an LDR with an init block
         * so we need to explicitly call it ourselves.  This will
         * reprogram our clocks, memory, and setup our async banks.
         */
        serial_early_puts("Program Clocks");

        /* if we're executing >=0x20000000, then we dont need to dma */
        r3 = 0x0;
        r3.h = 0x2000;
        cc = r5 < r3 (iu);
        if cc jump .Ldma_and_reprogram;
        call _initcode;
        jump .Lprogrammed;

        /* we're sitting in external memory, so dma into L1 and reprogram */
.Ldma_and_reprogram:
        r0.l = LO(L1_INST_SRAM);
        r0.h = HI(L1_INST_SRAM);
        r1.l = __initcode_start;
        r1.h = __initcode_start;
        r2.l = __initcode_end;
        r2.h = __initcode_end;
        r2 = r2 - r1;   /* convert r2 into length of initcode */
        r1 = r1 - r4;   /* convert r1 from load address of initcode ... */
        r1 = r1 + r5;   /* ... to current (not load) address of initcode */
        p3 = r0;
        call _dma_memcpy_nocache;
        call (p3);

        /* Since we reprogrammed SCLK, we need to update the serial divisor */
.Lprogrammed:
        serial_early_set_baud

        /* Relocate from wherever we are (FLASH/RAM/etc...) to the hardcoded
         * monitor location in the end of RAM.  We know that memcpy() only
         * uses registers, so it is safe to call here.  Note that this only
         * copies to external memory ... we do not start executing out of
         * it yet (see "lower to 15" below).
         */
        serial_early_puts("Relocate");
        r0 = r4;
        r1 = r5;
        r2.l = LO(CONFIG_SYS_MONITOR_LEN);
        r2.h = HI(CONFIG_SYS_MONITOR_LEN);
        call _memcpy_ASM;

        /* Initialize BSS section ... we know that memset() does not
         * use the BSS, so it is safe to call here.  The bootrom LDR
         * takes care of clearing things for us.
         */
        serial_early_puts("Zero BSS");
        r0.l = __bss_start;
        r0.h = __bss_start;
        r1 = 0 (x);
        r2.l = __bss_end;
        r2.h = __bss_end;
        r2 = r2 - r0;
        call _memset;

.Lnorelocate:

        /* Setup the actual stack in external memory */
        sp.h = HI(CONFIG_STACKBASE);
        sp.l = LO(CONFIG_STACKBASE);
        fp = sp;

        /* Now lower ourselves from the highest interrupt level to
         * the lowest.  We do this by masking all interrupts but 15,
         * setting the 15 handler to ".Lenable_nested", raising the 15
         * interrupt, and then returning from the highest interrupt
         * level to the dummy "jump" until the interrupt controller
         * services the pending 15 interrupt.  If executing out of
         * flash, these steps also changes the code flow from flash
         * to external memory.
         */
        serial_early_puts("Lower to 15");
        r0 = r7;
        r1 = r6;
        p0.l = LO(EVT15);
        p0.h = HI(EVT15);
        p1.l = .Lenable_nested;
        p1.h = .Lenable_nested;
        [p0] = p1;
        r7 = EVT_IVG15 (z);
        sti r7;
        raise 15;
        p4.l = .LWAIT_HERE;
        p4.h = .LWAIT_HERE;
        reti = p4;
        rti;

        /* Enable nested interrupts before continuing with cpu init */
.Lenable_nested:
        cli r7;
        [--sp] = reti;
        jump.l _cpu_init_f;

.LWAIT_HERE:
        jump .LWAIT_HERE;
ENDPROC(_start)

LENTRY(_get_pc)
        r0 = rets;
#if ANOMALY_05000371
        NOP;
        NOP;
        NOP;
#endif
        rts;
ENDPROC(_get_pc)