Pull thermal into release branch

[linux-drm-fsl-dcu.git] / arch / blackfin / mach-bf561 / head.S

/*
 * File:         arch/blackfin/mach-bf561/head.S
 * Based on:     arch/blackfin/mach-bf533/head.S
 * Author:
 *
 * Created:
 * Description:  BF561 startup file
 *
 * Modified:
 *               Copyright 2004-2006 Analog Devices Inc.
 *
 * Bugs:         Enter bugs at http://blackfin.uclinux.org/
 *
 * 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, see the file COPYING, or write
 * to the Free Software Foundation, Inc.,
 * 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA
 */

#include <linux/linkage.h>
#include <asm/blackfin.h>
#if CONFIG_BFIN_KERNEL_CLOCK
#include <asm/mach/mem_init.h>
#endif

.global __rambase
.global __ramstart
.global __ramend
.extern ___bss_stop
.extern ___bss_start
.extern _bf53x_relocate_l1_mem

#define INITIAL_STACK   0xFFB01000

.text

ENTRY(__start)
ENTRY(__stext)
        /*  R0: argument of command line string, passed from uboot, save it */
        R7 = R0;
        /* Set the SYSCFG register */
        R0 = 0x36;
        SYSCFG = R0; /*Enable Cycle Counter and Nesting Of Interrupts(3rd Bit)*/
        R0 = 0;

        /*Clear Out All the data and pointer  Registers*/
        R1 = R0;
        R2 = R0;
        R3 = R0;
        R4 = R0;
        R5 = R0;
        R6 = R0;

        P0 = R0;
        P1 = R0;
        P2 = R0;
        P3 = R0;
        P4 = R0;
        P5 = R0;

        LC0 = r0;
        LC1 = r0;
        L0 = r0;
        L1 = r0;
        L2 = r0;
        L3 = r0;

        /* Clear Out All the DAG Registers*/
        B0 = r0;
        B1 = r0;
        B2 = r0;
        B3 = r0;

        I0 = r0;
        I1 = r0;
        I2 = r0;
        I3 = r0;

        M0 = r0;
        M1 = r0;
        M2 = r0;
        M3 = r0;

        /* Turn off the icache */
        p0.l = (IMEM_CONTROL & 0xFFFF);
        p0.h = (IMEM_CONTROL >> 16);
        R1 = [p0];
        R0 = ~ENICPLB;
        R0 = R0 & R1;

        /* Anomaly 05000125 */
#ifdef ANOMALY_05000125
        CLI R2;
        SSYNC;
#endif
        [p0] = R0;
        SSYNC;
#ifdef ANOMALY_05000125
        STI R2;
#endif

        /* Turn off the dcache */
        p0.l = (DMEM_CONTROL & 0xFFFF);
        p0.h = (DMEM_CONTROL >> 16);
        R1 = [p0];
        R0 = ~ENDCPLB;
        R0 = R0 & R1;

        /* Anomaly 05000125 */
#ifdef ANOMALY_05000125
        CLI R2;
        SSYNC;
#endif
        [p0] = R0;
        SSYNC;
#ifdef ANOMALY_05000125
        STI R2;
#endif

        /* Initialise UART*/
        p0.h = hi(UART_LCR);
        p0.l = lo(UART_LCR);
        r0 = 0x0(Z);
        w[p0] = r0.L;   /* To enable DLL writes */
        ssync;

        p0.h = hi(UART_DLL);
        p0.l = lo(UART_DLL);
        r0 = 0x0(Z);
        w[p0] = r0.L;
        ssync;

        p0.h = hi(UART_DLH);
        p0.l = lo(UART_DLH);
        r0 = 0x00(Z);
        w[p0] = r0.L;
        ssync;

        p0.h = hi(UART_GCTL);
        p0.l = lo(UART_GCTL);
        r0 = 0x0(Z);
        w[p0] = r0.L;   /* To enable UART clock */
        ssync;

        /* Initialize stack pointer */
        sp.l = lo(INITIAL_STACK);
        sp.h = hi(INITIAL_STACK);
        fp = sp;
        usp = sp;

        /* Put The Code for PLL Programming and SDRAM Programming in L1 ISRAM */
        call _bf53x_relocate_l1_mem;
#if CONFIG_BFIN_KERNEL_CLOCK
        call _start_dma_code;
#endif

        /* Code for initializing Async memory banks */

        p2.h = hi(EBIU_AMBCTL1);
        p2.l = lo(EBIU_AMBCTL1);
        r0.h = hi(AMBCTL1VAL);
        r0.l = lo(AMBCTL1VAL);
        [p2] = r0;
        ssync;

        p2.h = hi(EBIU_AMBCTL0);
        p2.l = lo(EBIU_AMBCTL0);
        r0.h = hi(AMBCTL0VAL);
        r0.l = lo(AMBCTL0VAL);
        [p2] = r0;
        ssync;

        p2.h = hi(EBIU_AMGCTL);
        p2.l = lo(EBIU_AMGCTL);
        r0 = AMGCTLVAL;
        w[p2] = r0;
        ssync;

        /* This section keeps the processor in supervisor mode
         * during kernel boot.  Switches to user mode at end of boot.
         * See page 3-9 of Hardware Reference manual for documentation.
         */

        /* EVT15 = _real_start */

        p0.l = lo(EVT15);
        p0.h = hi(EVT15);
        p1.l = _real_start;
        p1.h = _real_start;
        [p0] = p1;
        csync;

        p0.l = lo(IMASK);
        p0.h = hi(IMASK);
        p1.l = IMASK_IVG15;
        p1.h = 0x0;
        [p0] = p1;
        csync;

        raise 15;
        p0.l = .LWAIT_HERE;
        p0.h = .LWAIT_HERE;
        reti = p0;
#if defined(ANOMALY_05000281)
        nop; nop; nop;
#endif
        rti;

.LWAIT_HERE:
        jump .LWAIT_HERE;

ENTRY(_real_start)
        [ -- sp ] = reti;
        p0.l = lo(WDOGA_CTL);
        p0.h = hi(WDOGA_CTL);
        r0 = 0xAD6(z);
        w[p0] = r0;     /* watchdog off for now */
        ssync;

        /* Code update for BSS size == 0
         * Zero out the bss region.
         */

        p1.l = ___bss_start;
        p1.h = ___bss_start;
        p2.l = ___bss_stop;
        p2.h = ___bss_stop;
        r0 = 0;
        p2 -= p1;
        lsetup (.L_clear_bss, .L_clear_bss ) lc0 = p2;
.L_clear_bss:
        B[p1++] = r0;

        /* In case there is a NULL pointer reference
         * Zero out region before stext
         */

        p1.l = 0x0;
        p1.h = 0x0;
        r0.l = __stext;
        r0.h = __stext;
        r0 = r0 >> 1;
        p2 = r0;
        r0 = 0;
        lsetup (.L_clear_zero, .L_clear_zero ) lc0 = p2;
.L_clear_zero:
        W[p1++] = r0;

/* pass the uboot arguments to the global value command line */
        R0 = R7;
        call _cmdline_init;

        p1.l = __rambase;
        p1.h = __rambase;
        r0.l = __sdata;
        r0.h = __sdata;
        [p1] = r0;

        p1.l = __ramstart;
        p1.h = __ramstart;
        p3.l = ___bss_stop;
        p3.h = ___bss_stop;

        r1 = p3;
        [p1] = r1;

        /*
         * load the current thread pointer and stack
         */
        r1.l = _init_thread_union;
        r1.h = _init_thread_union;

        r2.l = 0x2000;
        r2.h = 0x0000;
        r1 = r1 + r2;
        sp = r1;
        usp = sp;
        fp = sp;
        call _start_kernel;
.L_exit:
        jump.s  .L_exit;

.section .l1.text
#if CONFIG_BFIN_KERNEL_CLOCK
ENTRY(_start_dma_code)
        p0.h = hi(SICA_IWR0);
        p0.l = lo(SICA_IWR0);
        r0.l = 0x1;
        [p0] = r0;
        SSYNC;

        /*
         *  Set PLL_CTL
         *   - [14:09] = MSEL[5:0] : CLKIN / VCO multiplication factors
         *   - [8]     = BYPASS    : BYPASS the PLL, run CLKIN into CCLK/SCLK
         *   - [7]     = output delay (add 200ps of delay to mem signals)
         *   - [6]     = input delay (add 200ps of input delay to mem signals)
         *   - [5]     = PDWN      : 1=All Clocks off
         *   - [3]     = STOPCK    : 1=Core Clock off
         *   - [1]     = PLL_OFF   : 1=Disable Power to PLL
         *   - [0]     = DF        : 1=Pass CLKIN/2 to PLL / 0=Pass CLKIN to PLL
         *   all other bits set to zero
         */

        p0.h = hi(PLL_LOCKCNT);
        p0.l = lo(PLL_LOCKCNT);
        r0 = 0x300(Z);
        w[p0] = r0.l;
        ssync;

        P2.H = hi(EBIU_SDGCTL);
        P2.L = lo(EBIU_SDGCTL);
        R0 = [P2];
        BITSET (R0, 24);
        [P2] = R0;
        SSYNC;

        r0 = CONFIG_VCO_MULT & 63;       /* Load the VCO multiplier         */
        r0 = r0 << 9;                    /* Shift it over,                  */
        r1 = CLKIN_HALF;                 /* Do we need to divide CLKIN by 2?*/
        r0 = r1 | r0;
        r1 = PLL_BYPASS;                 /* Bypass the PLL?                 */
        r1 = r1 << 8;                    /* Shift it over                   */
        r0 = r1 | r0;                    /* add them all together           */

        p0.h = hi(PLL_CTL);
        p0.l = lo(PLL_CTL);              /* Load the address                */
        cli r2;                          /* Disable interrupts              */
        ssync;
        w[p0] = r0.l;                    /* Set the value                   */
        idle;                            /* Wait for the PLL to stablize    */
        sti r2;                          /* Enable interrupts               */

.Lcheck_again:
        p0.h = hi(PLL_STAT);
        p0.l = lo(PLL_STAT);
        R0 = W[P0](Z);
        CC = BITTST(R0,5);
        if ! CC jump .Lcheck_again;

        /* Configure SCLK & CCLK Dividers */
                r0 = (CONFIG_CCLK_ACT_DIV | CONFIG_SCLK_DIV);
        p0.h = hi(PLL_DIV);
        p0.l = lo(PLL_DIV);
        w[p0] = r0.l;
        ssync;

        p0.l = lo(EBIU_SDRRC);
        p0.h = hi(EBIU_SDRRC);
        r0 = mem_SDRRC;
        w[p0] = r0.l;
        ssync;

        p0.l = (EBIU_SDBCTL & 0xFFFF);
        p0.h = (EBIU_SDBCTL >> 16);     /* SDRAM Memory Bank Control Register */
        r0 = mem_SDBCTL;
        w[p0] = r0.l;
        ssync;

        P2.H = hi(EBIU_SDGCTL);
        P2.L = lo(EBIU_SDGCTL);
        R0 = [P2];
        BITCLR (R0, 24);
        p0.h = hi(EBIU_SDSTAT);
        p0.l = lo(EBIU_SDSTAT);
        r2.l = w[p0];
        cc = bittst(r2,3);
        if !cc jump .Lskip;
        NOP;
        BITSET (R0, 23);
.Lskip:
        [P2] = R0;
        SSYNC;

        R0.L = lo(mem_SDGCTL);
        R0.H = hi(mem_SDGCTL);
        R1 = [p2];
        R1 = R1 | R0;
        [P2] = R1;
        SSYNC;

        RTS;
#endif /* CONFIG_BFIN_KERNEL_CLOCK */

ENTRY(_bfin_reset)
        /* No more interrupts to be handled*/
        CLI R6;
        SSYNC;

#if defined(CONFIG_BFIN_SHARED_FLASH_ENET)
        p0.h = hi(FIO_INEN);
        p0.l = lo(FIO_INEN);
        r0.l = ~(PF1 | PF0);
        w[p0] = r0.l;

        p0.h = hi(FIO_DIR);
        p0.l = lo(FIO_DIR);
        r0.l = (PF1 | PF0);
        w[p0] = r0.l;

        p0.h = hi(FIO_FLAG_C);
        p0.l = lo(FIO_FLAG_C);
        r0.l = (PF1 | PF0);
        w[p0] = r0.l;
#endif

        /* Clear the bits 13-15 in SWRST if they werent cleared */
        p0.h = hi(SICA_SWRST);
        p0.l = lo(SICA_SWRST);
        csync;
        r0.l = w[p0];

        /* Clear the IMASK register */
        p0.h = hi(IMASK);
        p0.l = lo(IMASK);
        r0 = 0x0;
        [p0] = r0;

        /* Clear the ILAT register */
        p0.h = hi(ILAT);
        p0.l = lo(ILAT);
        r0 = [p0];
        [p0] = r0;
        SSYNC;

        /* Disable the WDOG TIMER */
        p0.h = hi(WDOGA_CTL);
        p0.l = lo(WDOGA_CTL);
        r0.l = 0xAD6;
        w[p0] = r0.l;
        SSYNC;

        /* Clear the sticky bit incase it is already set */
        p0.h = hi(WDOGA_CTL);
        p0.l = lo(WDOGA_CTL);
        r0.l = 0x8AD6;
        w[p0] = r0.l;
        SSYNC;

        /* Program the count value */
        R0.l = 0x100;
        R0.h = 0x0;
        P0.h = hi(WDOGA_CNT);
        P0.l = lo(WDOGA_CNT);
        [P0] = R0;
        SSYNC;

        /* Program WDOG_STAT if necessary */
        P0.h = hi(WDOGA_CTL);
        P0.l = lo(WDOGA_CTL);
        R0 = W[P0](Z);
        CC = BITTST(R0,1);
        if !CC JUMP .LWRITESTAT;
        CC = BITTST(R0,2);
        if !CC JUMP .LWRITESTAT;
        JUMP .LSKIP_WRITE;

.LWRITESTAT:
        /* When watch dog timer is enabled,
         * a write to STAT will load the contents of CNT to STAT
         */
        R0 = 0x0000(z);
        P0.h = hi(WDOGA_STAT);
        P0.l = lo(WDOGA_STAT)
        [P0] = R0;
        SSYNC;

.LSKIP_WRITE:
        /* Enable the reset event */
        P0.h = hi(WDOGA_CTL);
        P0.l = lo(WDOGA_CTL);
        R0 = W[P0](Z);
        BITCLR(R0,1);
        BITCLR(R0,2);
        W[P0] = R0.L;
        SSYNC;
        NOP;

        /* Enable the wdog counter */
        R0 = W[P0](Z);
        BITCLR(R0,4);
        W[P0] = R0.L;
        SSYNC;

        IDLE;

        RTS;

.data

/*
 * Set up the usable of RAM stuff. Size of RAM is determined then
 * an initial stack set up at the end.
 */

.align 4
__rambase:
.long   0
__ramstart:
.long   0
__ramend:
.long   0