Linux-libre 5.4.48-gnu

[librecmc/linux-libre.git] / arch / mips / netlogic / common / reset.S

/*
 * Copyright 2003-2013 Broadcom Corporation.
 * All Rights Reserved.
 *
 * This software is available to you under a choice of one of two
 * licenses.  You may choose to be licensed under the terms of the GNU
 * General Public License (GPL) Version 2, available from the file
 * COPYING in the main directory of this source tree, or the Broadcom
 * license below:
 *
 * Redistribution and use in source and binary forms, with or without
 * modification, are permitted provided that the following conditions
 * are met:
 *
 * 1. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 * 2. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in
 *    the documentation and/or other materials provided with the
 *    distribution.
 *
 * THIS SOFTWARE IS PROVIDED BY BROADCOM ``AS IS'' AND ANY EXPRESS OR
 * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 * ARE DISCLAIMED. IN NO EVENT SHALL BROADCOM OR CONTRIBUTORS BE LIABLE
 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
 * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
 * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
 * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
 * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */


#include <asm/asm.h>
#include <asm/asm-offsets.h>
#include <asm/cpu.h>
#include <asm/cacheops.h>
#include <asm/regdef.h>
#include <asm/mipsregs.h>
#include <asm/stackframe.h>
#include <asm/asmmacro.h>
#include <asm/addrspace.h>

#include <asm/netlogic/common.h>

#include <asm/netlogic/xlp-hal/iomap.h>
#include <asm/netlogic/xlp-hal/xlp.h>
#include <asm/netlogic/xlp-hal/sys.h>
#include <asm/netlogic/xlp-hal/cpucontrol.h>

#define SYS_CPU_COHERENT_BASE   CKSEG1ADDR(XLP_DEFAULT_IO_BASE) + \
                        XLP_IO_SYS_OFFSET(0) + XLP_IO_PCI_HDRSZ + \
                        SYS_CPU_NONCOHERENT_MODE * 4

/* Enable XLP features and workarounds in the LSU */
.macro xlp_config_lsu
        li      t0, LSU_DEFEATURE
        mfcr    t1, t0

        lui     t2, 0x4080      /* Enable Unaligned Access, L2HPE */
        or      t1, t1, t2
        mtcr    t1, t0

        li      t0, ICU_DEFEATURE
        mfcr    t1, t0
        ori     t1, 0x1000      /* Enable Icache partitioning */
        mtcr    t1, t0

        li      t0, SCHED_DEFEATURE
        lui     t1, 0x0100      /* Disable BRU accepting ALU ops */
        mtcr    t1, t0
.endm

/*
 * Allow access to physical mem >64G by enabling ELPA in PAGEGRAIN
 * register. This is needed before going to C code since the SP can
 * in this region. Called from all HW threads.
 */
.macro xlp_early_mmu_init
        mfc0    t0, CP0_PAGEMASK, 1
        li      t1, (1 << 29)           /* ELPA bit */
        or      t0, t1
        mtc0    t0, CP0_PAGEMASK, 1
.endm

/*
 * L1D cache has to be flushed before enabling threads in XLP.
 * On XLP8xx/XLP3xx, we do a low level flush using processor control
 * registers. On XLPII CPUs, usual cache instructions work.
 */
.macro  xlp_flush_l1_dcache
        mfc0    t0, CP0_PRID
        andi    t0, t0, PRID_IMP_MASK
        slt     t1, t0, 0x1200
        beqz    t1, 15f
        nop

        /* XLP8xx low level cache flush */
        li      t0, LSU_DEBUG_DATA0
        li      t1, LSU_DEBUG_ADDR
        li      t2, 0           /* index */
        li      t3, 0x1000      /* loop count */
11:
        sll     v0, t2, 5
        mtcr    zero, t0
        ori     v1, v0, 0x3     /* way0 | write_enable | write_active */
        mtcr    v1, t1
12:
        mfcr    v1, t1
        andi    v1, 0x1         /* wait for write_active == 0 */
        bnez    v1, 12b
        nop
        mtcr    zero, t0
        ori     v1, v0, 0x7     /* way1 | write_enable | write_active */
        mtcr    v1, t1
13:
        mfcr    v1, t1
        andi    v1, 0x1         /* wait for write_active == 0 */
        bnez    v1, 13b
        nop
        addi    t2, 1
        bne     t3, t2, 11b
        nop
        b       17f
        nop

        /* XLPII CPUs, Invalidate all 64k of L1 D-cache */
15:
        li      t0, 0x80000000
        li      t1, 0x80010000
16:     cache   Index_Writeback_Inv_D, 0(t0)
        addiu   t0, t0, 32
        bne     t0, t1, 16b
        nop
17:
.endm

/*
 * nlm_reset_entry will be copied to the reset entry point for
 * XLR and XLP. The XLP cores start here when they are woken up. This
 * is also the NMI entry point.
 *
 * We use scratch reg 6/7 to save k0/k1 and check for NMI first.
 *
 * The data corresponding to reset/NMI is stored at RESET_DATA_PHYS
 * location, this will have the thread mask (used when core is woken up)
 * and the current NMI handler in case we reached here for an NMI.
 *
 * When a core or thread is newly woken up, it marks itself ready and
 * loops in a 'wait'. When the CPU really needs waking up, we send an NMI
 * IPI to it, with the NMI handler set to prom_boot_secondary_cpus
 */
        .set    noreorder
        .set    noat
        .set    arch=xlr        /* for mfcr/mtcr, XLR is sufficient */

FEXPORT(nlm_reset_entry)
        dmtc0   k0, $22, 6
        dmtc0   k1, $22, 7
        mfc0    k0, CP0_STATUS
        li      k1, 0x80000
        and     k1, k0, k1
        beqz    k1, 1f          /* go to real reset entry */
        nop
        li      k1, CKSEG1ADDR(RESET_DATA_PHYS) /* NMI */
        ld      k0, BOOT_NMI_HANDLER(k1)
        jr      k0
        nop

1:      /* Entry point on core wakeup */
        mfc0    t0, CP0_PRID            /* processor ID */
        andi    t0, PRID_IMP_MASK
        li      t1, 0x1500              /* XLP 9xx */
        beq     t0, t1, 2f              /* does not need to set coherent */
        nop

        li      t1, 0x1300              /* XLP 5xx */
        beq     t0, t1, 2f              /* does not need to set coherent */
        nop

        /* set bit in SYS coherent register for the core */
        mfc0    t0, CP0_EBASE
        mfc0    t1, CP0_EBASE
        srl     t1, 5
        andi    t1, 0x3                 /* t1 <- node */
        li      t2, 0x40000
        mul     t3, t2, t1              /* t3 = node * 0x40000 */
        srl     t0, t0, 2
        and     t0, t0, 0x7             /* t0 <- core */
        li      t1, 0x1
        sll     t0, t1, t0
        nor     t0, t0, zero            /* t0 <- ~(1 << core) */
        li      t2, SYS_CPU_COHERENT_BASE
        add     t2, t2, t3              /* t2 <- SYS offset for node */
        lw      t1, 0(t2)
        and     t1, t1, t0
        sw      t1, 0(t2)

        /* read back to ensure complete */
        lw      t1, 0(t2)
        sync

2:
        /* Configure LSU on Non-0 Cores. */
        xlp_config_lsu
        /* FALL THROUGH */

/*
 * Wake up sibling threads from the initial thread in a core.
 */
EXPORT(nlm_boot_siblings)
        /* core L1D flush before enable threads */
        xlp_flush_l1_dcache
        /* save ra and sp, will be used later (only for boot cpu) */
        dmtc0   ra, $22, 6
        dmtc0   sp, $22, 7
        /* Enable hw threads by writing to MAP_THREADMODE of the core */
        li      t0, CKSEG1ADDR(RESET_DATA_PHYS)
        lw      t1, BOOT_THREAD_MODE(t0)        /* t1 <- thread mode */
        li      t0, ((CPU_BLOCKID_MAP << 8) | MAP_THREADMODE)
        mfcr    t2, t0
        or      t2, t2, t1
        mtcr    t2, t0

        /*
         * The new hardware thread starts at the next instruction
         * For all the cases other than core 0 thread 0, we will
         * jump to the secondary wait function.

         * NOTE: All GPR contents are lost after the mtcr above!
         */
        mfc0    v0, CP0_EBASE
        andi    v0, 0x3ff               /* v0 <- node/core */

        /*
         * Errata: to avoid potential live lock, setup IFU_BRUB_RESERVE
         * when running 4 threads per core
         */
        andi    v1, v0, 0x3             /* v1 <- thread id */
        bnez    v1, 2f
        nop

        /* thread 0 of each core. */
        li      t0, CKSEG1ADDR(RESET_DATA_PHYS)
        lw      t1, BOOT_THREAD_MODE(t0)        /* t1 <- thread mode */
        subu    t1, 0x3                         /* 4-thread per core mode? */
        bnez    t1, 2f
        nop

        li      t0, IFU_BRUB_RESERVE
        li      t1, 0x55
        mtcr    t1, t0
        _ehb
2:
        beqz    v0, 4f          /* boot cpu (cpuid == 0)? */
        nop

        /* setup status reg */
        move    t1, zero
#ifdef CONFIG_64BIT
        ori     t1, ST0_KX
#endif
        mtc0    t1, CP0_STATUS

        xlp_early_mmu_init

        /* mark CPU ready */
        li      t3, CKSEG1ADDR(RESET_DATA_PHYS)
        ADDIU   t1, t3, BOOT_CPU_READY
        sll     v1, v0, 2
        PTR_ADDU t1, v1
        li      t2, 1
        sw      t2, 0(t1)
        /* Wait until NMI hits */
3:      wait
        b       3b
        nop

        /*
         * For the boot CPU, we have to restore ra and sp and return, rest
         * of the registers will be restored by the caller
         */
4:
        dmfc0   ra, $22, 6
        dmfc0   sp, $22, 7
        jr      ra
        nop
EXPORT(nlm_reset_entry_end)

LEAF(nlm_init_boot_cpu)
#ifdef CONFIG_CPU_XLP
        xlp_config_lsu
        xlp_early_mmu_init
#endif
        jr      ra
        nop
END(nlm_init_boot_cpu)