arm/marvell/armadaxp.c

1.7  kiyohara /*	$NetBSD: armadaxp.c,v 1.7 2014/03/15 10:54:40 kiyohara Exp $	*/
1.1   rkujawa /*******************************************************************************
1.1   rkujawa Copyright (C) Marvell International Ltd. and its affiliates
1.1   rkujawa
1.1   rkujawa Developed by Semihalf
1.1   rkujawa
1.1   rkujawa ********************************************************************************
1.1   rkujawa Marvell BSD License
1.1   rkujawa
1.1   rkujawa If you received this File from Marvell, you may opt to use, redistribute and/or
1.1   rkujawa modify this File under the following licensing terms.
1.1   rkujawa Redistribution and use in source and binary forms, with or without modification,
1.1   rkujawa are permitted provided that the following conditions are met:
1.1   rkujawa
1.1   rkujawa     *   Redistributions of source code must retain the above copyright notice,
1.1   rkujawa             this list of conditions and the following disclaimer.
1.1   rkujawa
1.1   rkujawa     *   Redistributions in binary form must reproduce the above copyright
1.1   rkujawa         notice, this list of conditions and the following disclaimer in the
1.1   rkujawa         documentation and/or other materials provided with the distribution.
1.1   rkujawa
1.1   rkujawa     *   Neither the name of Marvell nor the names of its contributors may be
1.1   rkujawa         used to endorse or promote products derived from this software without
1.1   rkujawa         specific prior written permission.
1.1   rkujawa
1.1   rkujawa THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
1.1   rkujawa ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
1.1   rkujawa WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
1.1   rkujawa DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR
1.1   rkujawa ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
1.1   rkujawa (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
1.1   rkujawa LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
1.1   rkujawa ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1   rkujawa (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
1.1   rkujawa SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1   rkujawa
1.1   rkujawa *******************************************************************************/
1.1   rkujawa
1.1   rkujawa #include <sys/cdefs.h>
1.7  kiyohara __KERNEL_RCSID(0, "$NetBSD: armadaxp.c,v 1.7 2014/03/15 10:54:40 kiyohara Exp $");
1.1   rkujawa
1.1   rkujawa #define _INTR_PRIVATE
1.1   rkujawa
1.1   rkujawa #include "opt_mvsoc.h"
1.1   rkujawa
1.1   rkujawa #include <sys/param.h>
1.1   rkujawa #include <sys/bus.h>
1.1   rkujawa
1.1   rkujawa #include <machine/intr.h>
1.1   rkujawa
1.1   rkujawa #include <arm/pic/picvar.h>
1.1   rkujawa #include <arm/pic/picvar.h>
1.1   rkujawa
1.1   rkujawa #include <arm/armreg.h>
1.1   rkujawa #include <arm/cpu.h>
1.1   rkujawa #include <arm/cpufunc.h>
1.1   rkujawa
1.1   rkujawa #include <arm/marvell/mvsocreg.h>
1.1   rkujawa #include <arm/marvell/mvsocvar.h>
1.3  kiyohara #include <arm/marvell/armadaxpreg.h>
1.1   rkujawa
1.1   rkujawa #include <dev/marvell/marvellreg.h>
1.1   rkujawa
1.7  kiyohara #define EXTRACT_XP_CPU_FREQ_FIELD(sar)	(((0x01 & (sar >> 52)) << 3) | \
1.1   rkujawa 					    (0x07 & (sar >> 21)))
1.7  kiyohara #define EXTRACT_XP_FAB_FREQ_FIELD(sar)	(((0x01 & (sar >> 51)) << 4) | \
1.1   rkujawa 					    (0x0F & (sar >> 24)))
1.7  kiyohara #define EXTRACT_370_CPU_FREQ_FIELD(sar)	((sar >> 11) & 0xf)
1.7  kiyohara #define EXTRACT_370_FAB_FREQ_FIELD(sar)	((sar >> 15) & 0x1f)
1.1   rkujawa
1.1   rkujawa #define	MPIC_WRITE(reg, val)		(bus_space_write_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    mpic_handle, reg, val))
1.1   rkujawa #define	MPIC_CPU_WRITE(reg, val)	(bus_space_write_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    mpic_cpu_handle, reg, val))
1.1   rkujawa
1.1   rkujawa #define	MPIC_READ(reg)			(bus_space_read_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    mpic_handle, reg))
1.1   rkujawa #define	MPIC_CPU_READ(reg)		(bus_space_read_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    mpic_cpu_handle, reg))
1.1   rkujawa
1.1   rkujawa #define	L2_WRITE(reg, val)		(bus_space_write_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    l2_handle, reg, val))
1.1   rkujawa #define	L2_READ(reg)			(bus_space_read_4(&mvsoc_bs_tag, \
1.1   rkujawa 					    l2_handle, reg))
1.1   rkujawa bus_space_handle_t mpic_cpu_handle;
1.1   rkujawa static bus_space_handle_t mpic_handle, l2_handle;
1.1   rkujawa int l2cache_state = 0;
1.1   rkujawa int iocc_state = 0;
1.5  kiyohara #define read_miscreg(r)		(*(volatile uint32_t *)(misc_base + (r)))
1.5  kiyohara vaddr_t misc_base;
1.1   rkujawa
1.1   rkujawa extern void (*mvsoc_intr_init)(void);
1.1   rkujawa static void armadaxp_intr_init(void);
1.1   rkujawa
1.1   rkujawa static void armadaxp_pic_unblock_irqs(struct pic_softc *, size_t, uint32_t);
1.1   rkujawa static void armadaxp_pic_block_irqs(struct pic_softc *, size_t, uint32_t);
1.1   rkujawa static void armadaxp_pic_establish_irq(struct pic_softc *, struct intrsource *);
1.4  kiyohara static void armadaxp_pic_set_priority(struct pic_softc *, int);
1.1   rkujawa
1.4  kiyohara static int armadaxp_find_pending_irqs(void);
1.4  kiyohara static void armadaxp_pic_block_irq(struct pic_softc *, size_t);
1.1   rkujawa void armadaxp_io_coherency_init(void);
1.3  kiyohara int armadaxp_l2_init(bus_addr_t);
1.1   rkujawa
1.1   rkujawa struct vco_freq_ratio {
1.1   rkujawa 	uint8_t	vco_cpu;	/* VCO to CLK0(CPU) clock ratio */
1.1   rkujawa 	uint8_t	vco_l2c;	/* VCO to NB(L2 cache) clock ratio */
1.1   rkujawa 	uint8_t	vco_hcl;	/* VCO to HCLK(DDR controller) clock ratio */
1.1   rkujawa 	uint8_t	vco_ddr;	/* VCO to DR(DDR memory) clock ratio */
1.1   rkujawa };
1.1   rkujawa
1.1   rkujawa static struct vco_freq_ratio freq_conf_table[] = {
1.1   rkujawa /*00*/	{ 1, 1,	 4,  2 },
1.1   rkujawa /*01*/	{ 1, 2,	 2,  2 },
1.1   rkujawa /*02*/	{ 2, 2,	 6,  3 },
1.1   rkujawa /*03*/	{ 2, 2,	 3,  3 },
1.1   rkujawa /*04*/	{ 1, 2,	 3,  3 },
1.1   rkujawa /*05*/	{ 1, 2,	 4,  2 },
1.1   rkujawa /*06*/	{ 1, 1,	 2,  2 },
1.1   rkujawa /*07*/	{ 2, 3,	 6,  6 },
1.1   rkujawa /*08*/	{ 2, 3,	 5,  5 },
1.1   rkujawa /*09*/	{ 1, 2,	 6,  3 },
1.1   rkujawa /*10*/	{ 2, 4,	10,  5 },
1.1   rkujawa /*11*/	{ 1, 3,	 6,  6 },
1.1   rkujawa /*12*/	{ 1, 2,	 5,  5 },
1.1   rkujawa /*13*/	{ 1, 3,	 6,  3 },
1.1   rkujawa /*14*/	{ 1, 2,	 5,  5 },
1.1   rkujawa /*15*/	{ 2, 2,	 5,  5 },
1.1   rkujawa /*16*/	{ 1, 1,	 3,  3 },
1.1   rkujawa /*17*/	{ 2, 5,	10, 10 },
1.1   rkujawa /*18*/	{ 1, 3,	 8,  4 },
1.1   rkujawa /*19*/	{ 1, 1,	 2,  1 },
1.1   rkujawa /*20*/	{ 2, 3,	 6,  3 },
1.1   rkujawa /*21*/	{ 1, 2,	 8,  4 },
1.1   rkujawa /*22*/	{ 2, 5,	10,  5 }
1.1   rkujawa };
1.1   rkujawa
1.7  kiyohara static uint16_t clock_table_xp[] = {
1.7  kiyohara 	1000, 1066, 1200, 1333, 1500, 1666, 1800, 2000,
1.7  kiyohara 	 600,  667,  800, 1600, 2133, 2200, 2400
1.7  kiyohara };
1.7  kiyohara static uint16_t clock_table_370[] = {
1.7  kiyohara 	 400,  533,  667,  800, 1000, 1067, 1200, 1333,
1.7  kiyohara 	1500, 1600, 1667, 1800, 2000,  333,  600,  900,
1.7  kiyohara 	   0
1.7  kiyohara };
1.1   rkujawa
1.1   rkujawa static struct pic_ops armadaxp_picops = {
1.1   rkujawa 	.pic_unblock_irqs = armadaxp_pic_unblock_irqs,
1.1   rkujawa 	.pic_block_irqs = armadaxp_pic_block_irqs,
1.1   rkujawa 	.pic_establish_irq = armadaxp_pic_establish_irq,
1.4  kiyohara 	.pic_set_priority = armadaxp_pic_set_priority,
1.1   rkujawa };
1.1   rkujawa
1.1   rkujawa static struct pic_softc armadaxp_pic = {
1.1   rkujawa 	.pic_ops = &armadaxp_picops,
1.1   rkujawa 	.pic_name = "armadaxp",
1.1   rkujawa };
1.1   rkujawa
1.6  kiyohara static struct {
1.6  kiyohara 	bus_size_t offset;
1.6  kiyohara 	uint32_t bits;
1.6  kiyohara } clkgatings[]= {
1.6  kiyohara 	{ ARMADAXP_GBE3_BASE,	(1 << 1) },
1.6  kiyohara 	{ ARMADAXP_GBE2_BASE,	(1 << 2) },
1.6  kiyohara 	{ ARMADAXP_GBE1_BASE,	(1 << 3) },
1.6  kiyohara 	{ ARMADAXP_GBE0_BASE,	(1 << 4) },
1.6  kiyohara 	{ MVSOC_PEX_BASE,	(1 << 5) },
1.6  kiyohara 	{ ARMADAXP_PEX01_BASE,	(1 << 6) },
1.6  kiyohara 	{ ARMADAXP_PEX02_BASE,	(1 << 7) },
1.6  kiyohara 	{ ARMADAXP_PEX03_BASE,	(1 << 8) },
1.6  kiyohara 	{ ARMADAXP_PEX10_BASE,	(1 << 9) },
1.6  kiyohara 	{ ARMADAXP_PEX11_BASE,	(1 << 10) },
1.6  kiyohara 	{ ARMADAXP_PEX12_BASE,	(1 << 11) },
1.6  kiyohara 	{ ARMADAXP_PEX13_BASE,	(1 << 12) },
1.6  kiyohara #if 0
1.6  kiyohara 	{ NetA, (1 << 13) },
1.6  kiyohara #endif
1.6  kiyohara 	{ ARMADAXP_SATAHC_BASE,	(1 << 14) | (1 << 15) | (1 << 29) | (1 << 30) },
1.6  kiyohara 	{ ARMADAXP_LCD_BASE,	(1 << 16) },
1.6  kiyohara 	{ ARMADAXP_SDIO_BASE,	(1 << 17) },
1.6  kiyohara 	{ ARMADAXP_USB1_BASE,	(1 << 19) },
1.6  kiyohara 	{ ARMADAXP_USB2_BASE,	(1 << 20) },
1.6  kiyohara 	{ ARMADAXP_PEX2_BASE,	(1 << 26) },
1.6  kiyohara 	{ ARMADAXP_PEX3_BASE,	(1 << 27) },
1.6  kiyohara #if 0
1.6  kiyohara 	{ DDR, (1 << 28) },
1.6  kiyohara #endif
1.6  kiyohara };
1.6  kiyohara
1.1   rkujawa /*
1.1   rkujawa  * armadaxp_intr_bootstrap:
1.1   rkujawa  *
1.1   rkujawa  *	Initialize the rest of the interrupt subsystem, making it
1.1   rkujawa  *	ready to handle interrupts from devices.
1.1   rkujawa  */
1.1   rkujawa void
1.3  kiyohara armadaxp_intr_bootstrap(bus_addr_t pbase)
1.1   rkujawa {
1.1   rkujawa 	int i;
1.1   rkujawa
1.1   rkujawa 	/* Map MPIC base and MPIC percpu base registers */
1.3  kiyohara 	if (bus_space_map(&mvsoc_bs_tag, pbase + ARMADAXP_MLMB_MPIC_BASE,
1.3  kiyohara 	    0x500, 0, &mpic_handle) != 0)
1.1   rkujawa 		panic("%s: Could not map MPIC registers", __func__);
1.3  kiyohara 	if (bus_space_map(&mvsoc_bs_tag, pbase + ARMADAXP_MLMB_MPIC_CPU_BASE,
1.3  kiyohara 	    0x800, 0, &mpic_cpu_handle) != 0)
1.1   rkujawa 		panic("%s: Could not map MPIC percpu registers", __func__);
1.1   rkujawa
1.1   rkujawa 	/* Disable all interrupts */
1.1   rkujawa 	for (i = 0; i < 116; i++)
1.1   rkujawa 		MPIC_WRITE(ARMADAXP_MLMB_MPIC_ICE, i);
1.1   rkujawa
1.1   rkujawa 	mvsoc_intr_init = armadaxp_intr_init;
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa static void
1.1   rkujawa armadaxp_intr_init(void)
1.1   rkujawa {
1.1   rkujawa 	int ctrl;
1.1   rkujawa
1.1   rkujawa 	/* Get max interrupts */
1.1   rkujawa 	armadaxp_pic.pic_maxsources =
1.1   rkujawa 	    ((MPIC_READ(ARMADAXP_MLMB_MPIC_CTRL) >> 2) & 0x7FF);
1.1   rkujawa
1.1   rkujawa 	if (!armadaxp_pic.pic_maxsources)
1.1   rkujawa 		armadaxp_pic.pic_maxsources = 116;
1.1   rkujawa
1.1   rkujawa 	pic_add(&armadaxp_pic, 0);
1.1   rkujawa
1.1   rkujawa 	ctrl = MPIC_READ(ARMADAXP_MLMB_MPIC_CTRL);
1.1   rkujawa 	/* Enable IRQ prioritization */
1.1   rkujawa 	ctrl |= (1 << 0);
1.1   rkujawa 	MPIC_WRITE(ARMADAXP_MLMB_MPIC_CTRL, ctrl);
1.4  kiyohara
1.4  kiyohara 	find_pending_irqs = armadaxp_find_pending_irqs;
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa static void
1.1   rkujawa armadaxp_pic_unblock_irqs(struct pic_softc *pic, size_t irqbase,
1.1   rkujawa     uint32_t irq_mask)
1.1   rkujawa {
1.1   rkujawa 	int n;
1.1   rkujawa
1.1   rkujawa 	while (irq_mask != 0) {
1.1   rkujawa 		n = ffs(irq_mask) - 1;
1.1   rkujawa 		KASSERT(pic->pic_maxsources >= n + irqbase);
1.1   rkujawa 		MPIC_WRITE(ARMADAXP_MLMB_MPIC_ISE, n + irqbase);
1.1   rkujawa 		MPIC_CPU_WRITE(ARMADAXP_MLMB_MPIC_ICM, n + irqbase);
1.1   rkujawa 		if ((n + irqbase) == 0)
1.1   rkujawa 			MPIC_CPU_WRITE(ARMADAXP_MLMB_MPIC_DOORBELL_MASK,
1.1   rkujawa 			    0xffffffff);
1.1   rkujawa 		irq_mask &= ~__BIT(n);
1.1   rkujawa 	}
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa static void
1.1   rkujawa armadaxp_pic_block_irqs(struct pic_softc *pic, size_t irqbase,
1.1   rkujawa     uint32_t irq_mask)
1.1   rkujawa {
1.1   rkujawa 	int n;
1.1   rkujawa
1.1   rkujawa 	while (irq_mask != 0) {
1.1   rkujawa 		n = ffs(irq_mask) - 1;
1.1   rkujawa 		KASSERT(pic->pic_maxsources >= n + irqbase);
1.1   rkujawa 		MPIC_WRITE(ARMADAXP_MLMB_MPIC_ICE, n + irqbase);
1.1   rkujawa 		MPIC_CPU_WRITE(ARMADAXP_MLMB_MPIC_ISM, n + irqbase);
1.1   rkujawa 		irq_mask &= ~__BIT(n);
1.1   rkujawa 	}
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa static void
1.1   rkujawa armadaxp_pic_establish_irq(struct pic_softc *pic, struct intrsource *is)
1.1   rkujawa {
1.1   rkujawa 	int tmp;
1.1   rkujawa 	KASSERT(pic->pic_maxsources >= is->is_irq);
1.1   rkujawa 	tmp = MPIC_READ(ARMADAXP_MLMB_MPIC_ISCR_BASE + is->is_irq * 4);
1.1   rkujawa 	/* Clear previous priority */
1.1   rkujawa 	tmp &= ~(0xf << MPIC_ISCR_SHIFT);
1.1   rkujawa 	MPIC_WRITE(ARMADAXP_MLMB_MPIC_ISCR_BASE + is->is_irq * 4,
1.1   rkujawa 	    tmp | (is->is_ipl << MPIC_ISCR_SHIFT));
1.1   rkujawa }
1.1   rkujawa
1.4  kiyohara static void
1.4  kiyohara armadaxp_pic_set_priority(struct pic_softc *pic, int ipl)
1.4  kiyohara {
1.4  kiyohara 	int ctp;
1.4  kiyohara
1.4  kiyohara 	ctp = MPIC_CPU_READ(ARMADAXP_MLMB_MPIC_CTP);
1.4  kiyohara 	ctp &= ~(0xf << MPIC_CTP_SHIFT);
1.4  kiyohara 	ctp |= (ipl << MPIC_CTP_SHIFT);
1.4  kiyohara 	MPIC_CPU_WRITE(ARMADAXP_MLMB_MPIC_CTP, ctp);
1.4  kiyohara }
1.4  kiyohara
1.4  kiyohara static int
1.4  kiyohara armadaxp_find_pending_irqs(void)
1.1   rkujawa {
1.1   rkujawa 	struct intrsource *is;
1.1   rkujawa 	int irq;
1.1   rkujawa
1.1   rkujawa 	irq = MPIC_CPU_READ(ARMADAXP_MLMB_MPIC_IIACK) & 0x3ff;
1.1   rkujawa
1.1   rkujawa 	/* Is it a spurious interrupt ?*/
1.1   rkujawa 	if (irq == 0x3ff)
1.4  kiyohara 		return 0;
1.1   rkujawa 	is = armadaxp_pic.pic_sources[irq];
1.4  kiyohara 	if (is == NULL) {
1.4  kiyohara 		printf("stray interrupt: %d\n", irq);
1.4  kiyohara 		return 0;
1.1   rkujawa 	}
1.4  kiyohara
1.4  kiyohara 	armadaxp_pic_block_irq(&armadaxp_pic, irq);
1.4  kiyohara 	pic_mark_pending(&armadaxp_pic, irq);
1.4  kiyohara
1.4  kiyohara 	return is->is_ipl;
1.4  kiyohara }
1.4  kiyohara
1.4  kiyohara static void
1.4  kiyohara armadaxp_pic_block_irq(struct pic_softc *pic, size_t irq)
1.4  kiyohara {
1.4  kiyohara
1.4  kiyohara 	KASSERT(pic->pic_maxsources >= irq);
1.4  kiyohara 	MPIC_WRITE(ARMADAXP_MLMB_MPIC_ICE, irq);
1.4  kiyohara 	MPIC_CPU_WRITE(ARMADAXP_MLMB_MPIC_ISM, irq);
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa /*
1.1   rkujawa  * Clock functions
1.1   rkujawa  */
1.1   rkujawa
1.1   rkujawa void
1.1   rkujawa armadaxp_getclks(void)
1.1   rkujawa {
1.1   rkujawa 	uint64_t sar_reg;
1.7  kiyohara 	uint8_t  sar_cpu_freq, sar_fab_freq;
1.1   rkujawa
1.1   rkujawa 	if (cputype == CPU_ID_MV88SV584X_V7)
1.1   rkujawa 		mvTclk = 250000000; /* 250 MHz */
1.1   rkujawa 	else
1.1   rkujawa 		mvTclk = 200000000; /* 200 MHz */
1.1   rkujawa
1.1   rkujawa 	sar_reg = (read_miscreg(ARMADAXP_MISC_SAR_HI) << 31) |
1.1   rkujawa 	    read_miscreg(ARMADAXP_MISC_SAR_LO);
1.1   rkujawa
1.7  kiyohara 	sar_cpu_freq = EXTRACT_XP_CPU_FREQ_FIELD(sar_reg);
1.7  kiyohara 	sar_fab_freq = EXTRACT_XP_FAB_FREQ_FIELD(sar_reg);
1.1   rkujawa
1.1   rkujawa 	/* Check if CPU frequency field has correct value */
1.7  kiyohara 	if (sar_cpu_freq >= __arraycount(clock_table_xp))
1.1   rkujawa 		panic("Reserved value in cpu frequency configuration field: "
1.1   rkujawa 		    "%d", sar_cpu_freq);
1.1   rkujawa
1.1   rkujawa 	/* Check if fabric frequency field has correct value */
1.7  kiyohara 	if (sar_fab_freq >= __arraycount(freq_conf_table))
1.1   rkujawa 		panic("Reserved value in fabric frequency configuration field: "
1.1   rkujawa 		    "%d", sar_fab_freq);
1.1   rkujawa
1.1   rkujawa 	/* Get CPU clock frequency */
1.7  kiyohara 	mvPclk = clock_table_xp[sar_cpu_freq] *
1.1   rkujawa 	    freq_conf_table[sar_fab_freq].vco_cpu;
1.1   rkujawa
1.1   rkujawa 	/* Get L2CLK clock frequency and use as system clock (mvSysclk) */
1.1   rkujawa 	mvSysclk = mvPclk / freq_conf_table[sar_fab_freq].vco_l2c;
1.1   rkujawa
1.1   rkujawa 	/* Round mvSysclk value to integer MHz */
1.1   rkujawa 	if (((mvPclk % freq_conf_table[sar_fab_freq].vco_l2c) * 10 /
1.1   rkujawa 	    freq_conf_table[sar_fab_freq].vco_l2c) >= 5)
1.1   rkujawa 		mvSysclk++;
1.1   rkujawa
1.7  kiyohara 	mvPclk *= 1000000;
1.7  kiyohara 	mvSysclk *= 1000000;
1.7  kiyohara }
1.7  kiyohara
1.7  kiyohara void
1.7  kiyohara armada370_getclks(void)
1.7  kiyohara {
1.7  kiyohara 	uint32_t sar;
1.7  kiyohara 	uint8_t  cpu_freq, fab_freq;
1.7  kiyohara
1.7  kiyohara 	sar = read_miscreg(ARMADAXP_MISC_SAR_LO);
1.7  kiyohara 	if (sar & 0x00100000)
1.7  kiyohara 		mvTclk = 200000000; /* 200 MHz */
1.7  kiyohara 	else
1.7  kiyohara 		mvTclk = 166666667; /* 166 MHz */
1.7  kiyohara
1.7  kiyohara 	cpu_freq = EXTRACT_370_CPU_FREQ_FIELD(sar);
1.7  kiyohara 	fab_freq = EXTRACT_370_FAB_FREQ_FIELD(sar);
1.7  kiyohara
1.7  kiyohara 	/* Check if CPU frequency field has correct value */
1.7  kiyohara 	if (cpu_freq >= __arraycount(clock_table_370))
1.7  kiyohara 		panic("Reserved value in cpu frequency configuration field: "
1.7  kiyohara 		    "%d", cpu_freq);
1.7  kiyohara
1.7  kiyohara 	/* Check if fabric frequency field has correct value */
1.7  kiyohara 	if (fab_freq >= __arraycount(freq_conf_table))
1.7  kiyohara 		panic("Reserved value in fabric frequency configuration field: "
1.7  kiyohara 		    "%d", fab_freq);
1.7  kiyohara
1.7  kiyohara 	/* Get CPU clock frequency */
1.7  kiyohara 	mvPclk = clock_table_370[cpu_freq] *
1.7  kiyohara 	    freq_conf_table[fab_freq].vco_cpu;
1.7  kiyohara
1.7  kiyohara 	/* Get L2CLK clock frequency and use as system clock (mvSysclk) */
1.7  kiyohara 	mvSysclk = mvPclk / freq_conf_table[fab_freq].vco_l2c;
1.7  kiyohara
1.7  kiyohara 	/* Round mvSysclk value to integer MHz */
1.7  kiyohara 	if (((mvPclk % freq_conf_table[fab_freq].vco_l2c) * 10 /
1.7  kiyohara 	    freq_conf_table[fab_freq].vco_l2c) >= 5)
1.7  kiyohara 		mvSysclk++;
1.7  kiyohara
1.7  kiyohara 	mvPclk *= 1000000;
1.7  kiyohara 	mvSysclk *= 1000000;
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa /*
1.1   rkujawa  * L2 Cache initialization
1.1   rkujawa  */
1.1   rkujawa
1.1   rkujawa int
1.3  kiyohara armadaxp_l2_init(bus_addr_t pbase)
1.1   rkujawa {
1.1   rkujawa 	u_int32_t reg;
1.1   rkujawa 	int ret;
1.1   rkujawa
1.1   rkujawa 	/* Map L2 space */
1.3  kiyohara 	ret = bus_space_map(&mvsoc_bs_tag, pbase + ARMADAXP_L2_BASE,
1.3  kiyohara 	    0x1000, 0, &l2_handle);
1.1   rkujawa 	if (ret) {
1.1   rkujawa 		printf("%s: Cannot map L2 register space, ret:%d\n",
1.1   rkujawa 		    __func__, ret);
1.1   rkujawa 		return (-1);
1.1   rkujawa 	}
1.1   rkujawa
1.1   rkujawa 	/* Set L2 policy */
1.1   rkujawa 	reg = L2_READ(ARMADAXP_L2_AUX_CTRL);
1.1   rkujawa 	reg &= ~(L2_WBWT_MODE_MASK);
1.1   rkujawa 	reg &= ~(L2_REP_STRAT_MASK);
1.1   rkujawa 	reg |= L2_REP_STRAT_SEMIPLRU;
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_AUX_CTRL, reg);
1.1   rkujawa
1.1   rkujawa 	/* Invalidate L2 cache */
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_INV_WAY, L2_ALL_WAYS);
1.1   rkujawa
1.1   rkujawa 	/* Clear pending L2 interrupts */
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_INT_CAUSE, 0x1ff);
1.1   rkujawa
1.1   rkujawa 	/* Enable Cache and TLB maintenance broadcast */
1.1   rkujawa 	__asm__ __volatile__ ("mrc p15, 1, %0, c15, c2, 0" : "=r"(reg));
1.1   rkujawa 	reg |= (1 << 8);
1.1   rkujawa 	__asm__ __volatile__ ("mcr p15, 1, %0, c15, c2, 0" : :"r"(reg));
1.1   rkujawa
1.1   rkujawa 	/*
1.1   rkujawa 	 * Set the Point of Coherency and Point of Unification to DRAM.
1.1   rkujawa 	 * This is a reset value but anyway, configure this just in case.
1.1   rkujawa 	 */
1.1   rkujawa 	reg = read_mlmbreg(ARMADAXP_L2_CFU);
1.1   rkujawa 	reg |= (1 << 17) | (1 << 18);
1.1   rkujawa 	write_mlmbreg(ARMADAXP_L2_CFU, reg);
1.1   rkujawa
1.1   rkujawa 	/* Enable L2 cache */
1.1   rkujawa 	reg = L2_READ(ARMADAXP_L2_CTRL);
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_CTRL, reg | L2_ENABLE);
1.1   rkujawa
1.1   rkujawa 	/* Mark as enabled */
1.1   rkujawa 	l2cache_state = 1;
1.1   rkujawa
1.1   rkujawa #ifdef DEBUG
1.1   rkujawa 	/* Configure and enable counter */
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_CNTR_CONF(0), 0xf0000 | (4 << 2));
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_CNTR_CONF(1), 0xf0000 | (2 << 2));
1.1   rkujawa 	L2_WRITE(ARMADAXP_L2_CNTR_CTRL, 0x303);
1.1   rkujawa #endif
1.1   rkujawa
1.1   rkujawa 	return (0);
1.1   rkujawa }
1.1   rkujawa
1.1   rkujawa void
1.1   rkujawa armadaxp_io_coherency_init(void)
1.1   rkujawa {
1.1   rkujawa 	uint32_t reg;
1.1   rkujawa
1.1   rkujawa 	/* set CIB read snoop command to ReadUnique */
1.1   rkujawa 	reg = read_mlmbreg(MVSOC_MLMB_CIB_CTRL_CFG);
1.1   rkujawa 	reg &= ~(7 << 16);
1.1   rkujawa 	reg |= (7 << 16);
1.1   rkujawa 	write_mlmbreg(MVSOC_MLMB_CIB_CTRL_CFG, reg);
1.1   rkujawa 	/* enable CPUs in SMP group on Fabric coherency */
1.1   rkujawa 	reg = read_mlmbreg(MVSOC_MLMB_COHERENCY_FABRIC_CTRL);
1.1   rkujawa 	reg &= ~(0x3 << 24);
1.1   rkujawa 	reg |= (1 << 24);
1.1   rkujawa 	write_mlmbreg(MVSOC_MLMB_COHERENCY_FABRIC_CTRL, reg);
1.1   rkujawa
1.1   rkujawa 	reg = read_mlmbreg(MVSOC_MLMB_COHERENCY_FABRIC_CFG);
1.1   rkujawa 	reg &= ~(0x3 << 24);
1.1   rkujawa 	reg |= (1 << 24);
1.1   rkujawa 	write_mlmbreg(MVSOC_MLMB_COHERENCY_FABRIC_CFG, reg);
1.1   rkujawa
1.1   rkujawa 	/* Mark as enabled */
1.1   rkujawa 	iocc_state = 1;
1.1   rkujawa }
1.6  kiyohara
1.7  kiyohara int
1.6  kiyohara armadaxp_clkgating(struct marvell_attach_args *mva)
1.6  kiyohara {
1.6  kiyohara 	uint32_t val;
1.6  kiyohara 	int i;
1.6  kiyohara
1.6  kiyohara 	for (i = 0; i < __arraycount(clkgatings); i++) {
1.6  kiyohara 		if (clkgatings[i].offset == mva->mva_offset) {
1.6  kiyohara 			val = read_miscreg(ARMADAXP_MISC_PMCGC);
1.6  kiyohara 			if ((val & clkgatings[i].bits) == clkgatings[i].bits)
1.6  kiyohara 				/* Clock enabled */
1.7  kiyohara 				return 0;
1.6  kiyohara 			return 1;
1.6  kiyohara 		}
1.7  kiyohara 	}
1.6  kiyohara 	/* Clock Gating not support */
1.6  kiyohara 	return 0;
1.6  kiyohara }