drivers/marvell/mochi/cp110_setup.c - tf-a-mtk - Git at Google

 /*
  * Copyright (C) 2018 Marvell International Ltd.
  *
  * SPDX-License-Identifier:     BSD-3-Clause
  * https://spdx.org/licenses
  */

 /* CP110 Marvell SoC driver */

 #include <common/debug.h>
 #include <drivers/delay_timer.h>
 #include <drivers/marvell/amb_adec.h>
 #include <drivers/marvell/iob.h>
 #include <drivers/marvell/mochi/cp110_setup.h>

 #include <plat_marvell.h>

 /*
  * AXI Configuration.
  */

  /* Used for Units of CP-110 (e.g. USB device, USB Host, and etc) */
 #define MVEBU_AXI_ATTR_OFFSET			(0x441300)
 #define MVEBU_AXI_ATTR_REG(index)		(MVEBU_AXI_ATTR_OFFSET + \
 							0x4 * index)

 /* AXI Protection bits */
 #define MVEBU_AXI_PROT_OFFSET				(0x441200)

 /* AXI Protection regs */
 #define MVEBU_AXI_PROT_REG(index)		((index <= 4) ? \
 						(MVEBU_AXI_PROT_OFFSET + \
 							0x4 * index) : \
 						(MVEBU_AXI_PROT_OFFSET + 0x18))
 #define MVEBU_AXI_PROT_REGS_NUM			(6)

 #define MVEBU_SOC_CFGS_OFFSET			(0x441900)
 #define MVEBU_SOC_CFG_REG(index)		(MVEBU_SOC_CFGS_OFFSET + \
 							0x4 * index)
 #define MVEBU_SOC_CFG_REG_NUM			(0)
 #define MVEBU_SOC_CFG_GLOG_SECURE_EN_MASK	(0xE)

 /* SATA3 MBUS to AXI regs */
 #define MVEBU_BRIDGE_WIN_DIS_REG		(MVEBU_SOC_CFGS_OFFSET + 0x10)
 #define MVEBU_BRIDGE_WIN_DIS_OFF		(0x0)

 /* SATA3 MBUS to AXI regs */
 #define MVEBU_SATA_M2A_AXI_PORT_CTRL_REG	(0x54ff04)

 /* AXI to MBUS bridge registers */
 #define MVEBU_AMB_IP_OFFSET			(0x13ff00)
 #define MVEBU_AMB_IP_BRIDGE_WIN_REG(win)	(MVEBU_AMB_IP_OFFSET + \
 							(win * 0x8))
 #define MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET	0
 #define MVEBU_AMB_IP_BRIDGE_WIN_EN_MASK		\
 				(0x1 << MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET)
 #define MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET	16
 #define MVEBU_AMB_IP_BRIDGE_WIN_SIZE_MASK	\
 				(0xffffu << MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET)

 #define MVEBU_SAMPLE_AT_RESET_REG	(0x440600)
 #define SAR_PCIE1_CLK_CFG_OFFSET	31
 #define SAR_PCIE1_CLK_CFG_MASK		(0x1u << SAR_PCIE1_CLK_CFG_OFFSET)
 #define SAR_PCIE0_CLK_CFG_OFFSET	30
 #define SAR_PCIE0_CLK_CFG_MASK		(0x1 << SAR_PCIE0_CLK_CFG_OFFSET)
 #define SAR_I2C_INIT_EN_OFFSET		24
 #define SAR_I2C_INIT_EN_MASK		(1 << SAR_I2C_INIT_EN_OFFSET)

 /*******************************************************************************
  * PCIE clock buffer control
  ******************************************************************************/
 #define MVEBU_PCIE_REF_CLK_BUF_CTRL			(0x4404F0)
 #define PCIE1_REFCLK_BUFF_SOURCE			0x800
 #define PCIE0_REFCLK_BUFF_SOURCE			0x400

 /*******************************************************************************
  * MSS Device Push Set Register
  ******************************************************************************/
 #define MVEBU_CP_MSS_DPSHSR_REG				(0x280040)
 #define MSS_DPSHSR_REG_PCIE_CLK_SEL			0x8

 /*******************************************************************************
  * RTC Configuration
  ******************************************************************************/
 #define MVEBU_RTC_BASE					(0x284000)
 #define MVEBU_RTC_STATUS_REG				(MVEBU_RTC_BASE + 0x0)
 #define MVEBU_RTC_STATUS_ALARM1_MASK			0x1
 #define MVEBU_RTC_STATUS_ALARM2_MASK			0x2
 #define MVEBU_RTC_IRQ_1_CONFIG_REG			(MVEBU_RTC_BASE + 0x4)
 #define MVEBU_RTC_IRQ_2_CONFIG_REG			(MVEBU_RTC_BASE + 0x8)
 #define MVEBU_RTC_TIME_REG				(MVEBU_RTC_BASE + 0xC)
 #define MVEBU_RTC_ALARM_1_REG				(MVEBU_RTC_BASE + 0x10)
 #define MVEBU_RTC_ALARM_2_REG				(MVEBU_RTC_BASE + 0x14)
 #define MVEBU_RTC_CCR_REG				(MVEBU_RTC_BASE + 0x18)
 #define MVEBU_RTC_NOMINAL_TIMING			0x2000
 #define MVEBU_RTC_NOMINAL_TIMING_MASK			0x7FFF
 #define MVEBU_RTC_TEST_CONFIG_REG			(MVEBU_RTC_BASE + 0x1C)
 #define MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG		(MVEBU_RTC_BASE + 0x80)
 #define MVEBU_RTC_WRCLK_PERIOD_MASK			0xFFFF
 #define MVEBU_RTC_WRCLK_PERIOD_DEFAULT			0x3FF
 #define MVEBU_RTC_WRCLK_SETUP_OFFS			16
 #define MVEBU_RTC_WRCLK_SETUP_MASK			0xFFFF0000
 #define MVEBU_RTC_WRCLK_SETUP_DEFAULT			0x29
 #define MVEBU_RTC_BRIDGE_TIMING_CTRL1_REG		(MVEBU_RTC_BASE + 0x84)
 #define MVEBU_RTC_READ_OUTPUT_DELAY_MASK		0xFFFF
 #define MVEBU_RTC_READ_OUTPUT_DELAY_DEFAULT		0x1F

 enum axi_attr {
 	AXI_ADUNIT_ATTR = 0,
 	AXI_COMUNIT_ATTR,
 	AXI_EIP197_ATTR,
 	AXI_USB3D_ATTR,
 	AXI_USB3H0_ATTR,
 	AXI_USB3H1_ATTR,
 	AXI_SATA0_ATTR,
 	AXI_SATA1_ATTR,
 	AXI_DAP_ATTR,
 	AXI_DFX_ATTR,
 	AXI_DBG_TRC_ATTR = 12,
 	AXI_SDIO_ATTR,
 	AXI_MSS_ATTR,
 	AXI_MAX_ATTR,
 };

 /* Most stream IDS are configured centrally in the CP-110 RFU
  * but some are configured inside the unit registers
  */
 #define RFU_STREAM_ID_BASE	(0x450000)
 #define USB3H_0_STREAM_ID_REG	(RFU_STREAM_ID_BASE + 0xC)
 #define USB3H_1_STREAM_ID_REG	(RFU_STREAM_ID_BASE + 0x10)
 #define SATA_0_STREAM_ID_REG	(RFU_STREAM_ID_BASE + 0x14)
 #define SATA_1_STREAM_ID_REG	(RFU_STREAM_ID_BASE + 0x18)

 #define CP_DMA_0_STREAM_ID_REG  (0x6B0010)
 #define CP_DMA_1_STREAM_ID_REG  (0x6D0010)

 /* We allocate IDs 128-255 for PCIe */
 #define MAX_STREAM_ID		(0x80)

 uintptr_t stream_id_reg[] = {
 	USB3H_0_STREAM_ID_REG,
 	USB3H_1_STREAM_ID_REG,
 	CP_DMA_0_STREAM_ID_REG,
 	CP_DMA_1_STREAM_ID_REG,
 	SATA_0_STREAM_ID_REG,
 	SATA_1_STREAM_ID_REG,
 	0
 };

 static void cp110_errata_wa_init(uintptr_t base)
 {
 	uint32_t data;

 	/* ERRATA GL-4076863:
 	 * Reset value for global_secure_enable inputs must be changed
 	 * from '1' to '0'.
 	 * When asserted, only "secured" transactions can enter IHB
 	 * configuration space.
 	 * However, blocking AXI transactions is performed by IOB.
 	 * Performing it also at IHB/HB complicates programming model.
 	 *
 	 * Enable non-secure access in SOC configuration register
 	 */
 	data = mmio_read_32(base + MVEBU_SOC_CFG_REG(MVEBU_SOC_CFG_REG_NUM));
 	data &= ~MVEBU_SOC_CFG_GLOG_SECURE_EN_MASK;
 	mmio_write_32(base + MVEBU_SOC_CFG_REG(MVEBU_SOC_CFG_REG_NUM), data);
 }

 static void cp110_pcie_clk_cfg(uintptr_t base)
 {
 	uint32_t pcie0_clk, pcie1_clk, reg;

 	/*
 	 * Determine the pcie0/1 clock direction (input/output) from the
 	 * sample at reset.
 	 */
 	reg = mmio_read_32(base + MVEBU_SAMPLE_AT_RESET_REG);
 	pcie0_clk = (reg & SAR_PCIE0_CLK_CFG_MASK) >> SAR_PCIE0_CLK_CFG_OFFSET;
 	pcie1_clk = (reg & SAR_PCIE1_CLK_CFG_MASK) >> SAR_PCIE1_CLK_CFG_OFFSET;

 	/* CP110 revision A2 */
 	if (cp110_rev_id_get(base) == MVEBU_CP110_REF_ID_A2) {
 		/*
 		 * PCIe Reference Clock Buffer Control register must be
 		 * set according to the clock direction (input/output)
 		 */
 		reg = mmio_read_32(base + MVEBU_PCIE_REF_CLK_BUF_CTRL);
 		reg &= ~(PCIE0_REFCLK_BUFF_SOURCE | PCIE1_REFCLK_BUFF_SOURCE);
 		if (!pcie0_clk)
 			reg |= PCIE0_REFCLK_BUFF_SOURCE;
 		if (!pcie1_clk)
 			reg |= PCIE1_REFCLK_BUFF_SOURCE;

 		mmio_write_32(base + MVEBU_PCIE_REF_CLK_BUF_CTRL, reg);
 	}

 	/* CP110 revision A1 */
 	if (cp110_rev_id_get(base) == MVEBU_CP110_REF_ID_A1) {
 		if (!pcie0_clk || !pcie1_clk) {
 			/*
 			 * if one of the pcie clocks is set to input,
 			 * we need to set mss_push[131] field, otherwise,
 			 * the pcie clock might not work.
 			 */
 			reg = mmio_read_32(base + MVEBU_CP_MSS_DPSHSR_REG);
 			reg |= MSS_DPSHSR_REG_PCIE_CLK_SEL;
 			mmio_write_32(base + MVEBU_CP_MSS_DPSHSR_REG, reg);
 		}
 	}
 }

 /* Set a unique stream id for all DMA capable devices */
 static void cp110_stream_id_init(uintptr_t base, uint32_t stream_id)
 {
 	int i = 0;

 	while (stream_id_reg[i]) {
 		if (i > MAX_STREAM_ID_PER_CP) {
 			NOTICE("Only first %d (maximum) Stream IDs allocated\n",
 			       MAX_STREAM_ID_PER_CP);
 			return;
 		}

 		if ((stream_id_reg[i] == CP_DMA_0_STREAM_ID_REG) ||
 		    (stream_id_reg[i] == CP_DMA_1_STREAM_ID_REG))
 			mmio_write_32(base + stream_id_reg[i],
 				      stream_id << 16 |  stream_id);
 		else
 			mmio_write_32(base + stream_id_reg[i], stream_id);

 		/* SATA port 0/1 are in the same SATA unit, and they should use
 		 * the same STREAM ID number
 		 */
 		if (stream_id_reg[i] != SATA_0_STREAM_ID_REG)
 			stream_id++;

 		i++;
 	}
 }

 static void cp110_axi_attr_init(uintptr_t base)
 {
 	uint32_t index, data;

 	/* Initialize AXI attributes for Armada-7K/8K SoC */

 	/* Go over the AXI attributes and set Ax-Cache and Ax-Domain */
 	for (index = 0; index < AXI_MAX_ATTR; index++) {
 		switch (index) {
 		/* DFX and MSS unit works with no coherent only -
 		 * there's no option to configure the Ax-Cache and Ax-Domain
 		 */
 		case AXI_DFX_ATTR:
 		case AXI_MSS_ATTR:
 			continue;
 		default:
 			/* Set Ax-Cache as cacheable, no allocate, modifiable,
 			 * bufferable
 			 * The values are different because Read & Write
 			 * definition is different in Ax-Cache
 			 */
 			data = mmio_read_32(base + MVEBU_AXI_ATTR_REG(index));
 			data &= ~MVEBU_AXI_ATTR_ARCACHE_MASK;
 			data |= (CACHE_ATTR_WRITE_ALLOC |
 				 CACHE_ATTR_CACHEABLE   |
 				 CACHE_ATTR_BUFFERABLE) <<
 				 MVEBU_AXI_ATTR_ARCACHE_OFFSET;
 			data &= ~MVEBU_AXI_ATTR_AWCACHE_MASK;
 			data |= (CACHE_ATTR_READ_ALLOC |
 				 CACHE_ATTR_CACHEABLE  |
 				 CACHE_ATTR_BUFFERABLE) <<
 				 MVEBU_AXI_ATTR_AWCACHE_OFFSET;
 			/* Set Ax-Domain as Outer domain */
 			data &= ~MVEBU_AXI_ATTR_ARDOMAIN_MASK;
 			data |= DOMAIN_OUTER_SHAREABLE <<
 				MVEBU_AXI_ATTR_ARDOMAIN_OFFSET;
 			data &= ~MVEBU_AXI_ATTR_AWDOMAIN_MASK;
 			data |= DOMAIN_OUTER_SHAREABLE <<
 				MVEBU_AXI_ATTR_AWDOMAIN_OFFSET;
 			mmio_write_32(base + MVEBU_AXI_ATTR_REG(index), data);
 		}
 	}

 	/* SATA IOCC supported, cache attributes
 	 * for SATA MBUS to AXI configuration.
 	 */
 	data = mmio_read_32(base + MVEBU_SATA_M2A_AXI_PORT_CTRL_REG);
 	data &= ~MVEBU_SATA_M2A_AXI_AWCACHE_MASK;
 	data |= (CACHE_ATTR_WRITE_ALLOC |
 		 CACHE_ATTR_CACHEABLE   |
 		 CACHE_ATTR_BUFFERABLE) <<
 		 MVEBU_SATA_M2A_AXI_AWCACHE_OFFSET;
 	data &= ~MVEBU_SATA_M2A_AXI_ARCACHE_MASK;
 	data |= (CACHE_ATTR_READ_ALLOC |
 		 CACHE_ATTR_CACHEABLE  |
 		 CACHE_ATTR_BUFFERABLE) <<
 		 MVEBU_SATA_M2A_AXI_ARCACHE_OFFSET;
 	mmio_write_32(base + MVEBU_SATA_M2A_AXI_PORT_CTRL_REG, data);

 	/* Set all IO's AXI attribute to non-secure access. */
 	for (index = 0; index < MVEBU_AXI_PROT_REGS_NUM; index++)
 		mmio_write_32(base + MVEBU_AXI_PROT_REG(index),
 			      DOMAIN_SYSTEM_SHAREABLE);
 }

 static void amb_bridge_init(uintptr_t base)
 {
 	uint32_t reg;

 	/* Open AMB bridge Window to Access COMPHY/MDIO registers */
 	reg = mmio_read_32(base + MVEBU_AMB_IP_BRIDGE_WIN_REG(0));
 	reg &= ~(MVEBU_AMB_IP_BRIDGE_WIN_SIZE_MASK |
 		 MVEBU_AMB_IP_BRIDGE_WIN_EN_MASK);
 	reg |= (0x7ff << MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET) |
 	       (0x1 << MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET);
 	mmio_write_32(base + MVEBU_AMB_IP_BRIDGE_WIN_REG(0), reg);
 }

 static void cp110_rtc_init(uintptr_t base)
 {
 	/* Update MBus timing parameters before accessing RTC registers */
 	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG,
 			   MVEBU_RTC_WRCLK_PERIOD_MASK,
 			   MVEBU_RTC_WRCLK_PERIOD_DEFAULT);

 	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG,
 			   MVEBU_RTC_WRCLK_SETUP_MASK,
 			   MVEBU_RTC_WRCLK_SETUP_DEFAULT <<
 			   MVEBU_RTC_WRCLK_SETUP_OFFS);

 	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL1_REG,
 			   MVEBU_RTC_READ_OUTPUT_DELAY_MASK,
 			   MVEBU_RTC_READ_OUTPUT_DELAY_DEFAULT);

 	/*
 	 * Issue reset to the RTC if Clock Correction register
 	 * contents did not sustain the reboot/power-on.
 	 */
 	if ((mmio_read_32(base + MVEBU_RTC_CCR_REG) &
 	    MVEBU_RTC_NOMINAL_TIMING_MASK) != MVEBU_RTC_NOMINAL_TIMING) {
 		/* Reset Test register */
 		mmio_write_32(base + MVEBU_RTC_TEST_CONFIG_REG, 0);
 		mdelay(500);

 		/* Reset Status register */
 		mmio_write_32(base + MVEBU_RTC_STATUS_REG,
 			      (MVEBU_RTC_STATUS_ALARM1_MASK |
 			      MVEBU_RTC_STATUS_ALARM2_MASK));
 		udelay(62);

 		/* Turn off Int1 and Int2 sources & clear the Alarm count */
 		mmio_write_32(base + MVEBU_RTC_IRQ_1_CONFIG_REG, 0);
 		mmio_write_32(base + MVEBU_RTC_IRQ_2_CONFIG_REG, 0);
 		mmio_write_32(base + MVEBU_RTC_ALARM_1_REG, 0);
 		mmio_write_32(base + MVEBU_RTC_ALARM_2_REG, 0);

 		/* Setup nominal register access timing */
 		mmio_write_32(base + MVEBU_RTC_CCR_REG,
 			      MVEBU_RTC_NOMINAL_TIMING);

 		/* Reset Status register */
 		mmio_write_32(base + MVEBU_RTC_STATUS_REG,
 			      (MVEBU_RTC_STATUS_ALARM1_MASK |
 			      MVEBU_RTC_STATUS_ALARM2_MASK));
 		udelay(50);
 	}
 }

 static void cp110_amb_adec_init(uintptr_t base)
 {
 	/* enable AXI-MBUS by clearing "Bridge Windows Disable" */
 	mmio_clrbits_32(base + MVEBU_BRIDGE_WIN_DIS_REG,
 			(1 << MVEBU_BRIDGE_WIN_DIS_OFF));

 	/* configure AXI-MBUS windows for CP */
 	init_amb_adec(base);
 }

 void cp110_init(uintptr_t cp110_base, uint32_t stream_id)
 {
 	INFO("%s: Initialize CPx - base = %lx\n", __func__, cp110_base);

 	/* configure IOB windows for CP0*/
 	init_iob(cp110_base);

 	/* configure AXI-MBUS windows for CP0*/
 	cp110_amb_adec_init(cp110_base);

 	/* configure axi for CP0*/
 	cp110_axi_attr_init(cp110_base);

 	/* Execute SW WA for erratas */
 	cp110_errata_wa_init(cp110_base);

 	/* Confiure pcie clock according to clock direction */
 	cp110_pcie_clk_cfg(cp110_base);

 	/* configure stream id for CP0 */
 	cp110_stream_id_init(cp110_base, stream_id);

 	/* Open AMB bridge for comphy for CP0 & CP1*/
 	amb_bridge_init(cp110_base);

 	/* Reset RTC if needed */
 	cp110_rtc_init(cp110_base);
 }

 /* Do the minimal setup required to configure the CP in BLE */
 void cp110_ble_init(uintptr_t cp110_base)
 {
 #if PCI_EP_SUPPORT
 	INFO("%s: Initialize CPx - base = %lx\n", __func__, cp110_base);

 	amb_bridge_init(cp110_base);

 	/* Configure PCIe clock */
 	cp110_pcie_clk_cfg(cp110_base);

 	/* Configure PCIe endpoint */
 	ble_plat_pcie_ep_setup();
 #endif
 }
	/*
	* Copyright (C) 2018 Marvell International Ltd.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	* https://spdx.org/licenses
	*/

	/* CP110 Marvell SoC driver */

	#include <common/debug.h>
	#include <drivers/delay_timer.h>
	#include <drivers/marvell/amb_adec.h>
	#include <drivers/marvell/iob.h>
	#include <drivers/marvell/mochi/cp110_setup.h>

	#include <plat_marvell.h>

	/*
	* AXI Configuration.
	*/

	/* Used for Units of CP-110 (e.g. USB device, USB Host, and etc) */
	#define MVEBU_AXI_ATTR_OFFSET (0x441300)
	#define MVEBU_AXI_ATTR_REG(index) (MVEBU_AXI_ATTR_OFFSET + \
	0x4 * index)

	/* AXI Protection bits */
	#define MVEBU_AXI_PROT_OFFSET (0x441200)

	/* AXI Protection regs */
	#define MVEBU_AXI_PROT_REG(index) ((index <= 4) ? \
	(MVEBU_AXI_PROT_OFFSET + \
	0x4 * index) : \
	(MVEBU_AXI_PROT_OFFSET + 0x18))
	#define MVEBU_AXI_PROT_REGS_NUM (6)

	#define MVEBU_SOC_CFGS_OFFSET (0x441900)
	#define MVEBU_SOC_CFG_REG(index) (MVEBU_SOC_CFGS_OFFSET + \
	0x4 * index)
	#define MVEBU_SOC_CFG_REG_NUM (0)
	#define MVEBU_SOC_CFG_GLOG_SECURE_EN_MASK (0xE)

	/* SATA3 MBUS to AXI regs */
	#define MVEBU_BRIDGE_WIN_DIS_REG (MVEBU_SOC_CFGS_OFFSET + 0x10)
	#define MVEBU_BRIDGE_WIN_DIS_OFF (0x0)

	/* SATA3 MBUS to AXI regs */
	#define MVEBU_SATA_M2A_AXI_PORT_CTRL_REG (0x54ff04)

	/* AXI to MBUS bridge registers */
	#define MVEBU_AMB_IP_OFFSET (0x13ff00)
	#define MVEBU_AMB_IP_BRIDGE_WIN_REG(win) (MVEBU_AMB_IP_OFFSET + \
	(win * 0x8))
	#define MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET 0
	#define MVEBU_AMB_IP_BRIDGE_WIN_EN_MASK \
	(0x1 << MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET)
	#define MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET 16
	#define MVEBU_AMB_IP_BRIDGE_WIN_SIZE_MASK \
	(0xffffu << MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET)

	#define MVEBU_SAMPLE_AT_RESET_REG (0x440600)
	#define SAR_PCIE1_CLK_CFG_OFFSET 31
	#define SAR_PCIE1_CLK_CFG_MASK (0x1u << SAR_PCIE1_CLK_CFG_OFFSET)
	#define SAR_PCIE0_CLK_CFG_OFFSET 30
	#define SAR_PCIE0_CLK_CFG_MASK (0x1 << SAR_PCIE0_CLK_CFG_OFFSET)
	#define SAR_I2C_INIT_EN_OFFSET 24
	#define SAR_I2C_INIT_EN_MASK (1 << SAR_I2C_INIT_EN_OFFSET)

	/*******************************************************************************
	* PCIE clock buffer control
	******************************************************************************/
	#define MVEBU_PCIE_REF_CLK_BUF_CTRL (0x4404F0)
	#define PCIE1_REFCLK_BUFF_SOURCE 0x800
	#define PCIE0_REFCLK_BUFF_SOURCE 0x400

	/*******************************************************************************
	* MSS Device Push Set Register
	******************************************************************************/
	#define MVEBU_CP_MSS_DPSHSR_REG (0x280040)
	#define MSS_DPSHSR_REG_PCIE_CLK_SEL 0x8

	/*******************************************************************************
	* RTC Configuration
	******************************************************************************/
	#define MVEBU_RTC_BASE (0x284000)
	#define MVEBU_RTC_STATUS_REG (MVEBU_RTC_BASE + 0x0)
	#define MVEBU_RTC_STATUS_ALARM1_MASK 0x1
	#define MVEBU_RTC_STATUS_ALARM2_MASK 0x2
	#define MVEBU_RTC_IRQ_1_CONFIG_REG (MVEBU_RTC_BASE + 0x4)
	#define MVEBU_RTC_IRQ_2_CONFIG_REG (MVEBU_RTC_BASE + 0x8)
	#define MVEBU_RTC_TIME_REG (MVEBU_RTC_BASE + 0xC)
	#define MVEBU_RTC_ALARM_1_REG (MVEBU_RTC_BASE + 0x10)
	#define MVEBU_RTC_ALARM_2_REG (MVEBU_RTC_BASE + 0x14)
	#define MVEBU_RTC_CCR_REG (MVEBU_RTC_BASE + 0x18)
	#define MVEBU_RTC_NOMINAL_TIMING 0x2000
	#define MVEBU_RTC_NOMINAL_TIMING_MASK 0x7FFF
	#define MVEBU_RTC_TEST_CONFIG_REG (MVEBU_RTC_BASE + 0x1C)
	#define MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG (MVEBU_RTC_BASE + 0x80)
	#define MVEBU_RTC_WRCLK_PERIOD_MASK 0xFFFF
	#define MVEBU_RTC_WRCLK_PERIOD_DEFAULT 0x3FF
	#define MVEBU_RTC_WRCLK_SETUP_OFFS 16
	#define MVEBU_RTC_WRCLK_SETUP_MASK 0xFFFF0000
	#define MVEBU_RTC_WRCLK_SETUP_DEFAULT 0x29
	#define MVEBU_RTC_BRIDGE_TIMING_CTRL1_REG (MVEBU_RTC_BASE + 0x84)
	#define MVEBU_RTC_READ_OUTPUT_DELAY_MASK 0xFFFF
	#define MVEBU_RTC_READ_OUTPUT_DELAY_DEFAULT 0x1F

	enum axi_attr {
	AXI_ADUNIT_ATTR = 0,
	AXI_COMUNIT_ATTR,
	AXI_EIP197_ATTR,
	AXI_USB3D_ATTR,
	AXI_USB3H0_ATTR,
	AXI_USB3H1_ATTR,
	AXI_SATA0_ATTR,
	AXI_SATA1_ATTR,
	AXI_DAP_ATTR,
	AXI_DFX_ATTR,
	AXI_DBG_TRC_ATTR = 12,
	AXI_SDIO_ATTR,
	AXI_MSS_ATTR,
	AXI_MAX_ATTR,
	};

	/* Most stream IDS are configured centrally in the CP-110 RFU
	* but some are configured inside the unit registers
	*/
	#define RFU_STREAM_ID_BASE (0x450000)
	#define USB3H_0_STREAM_ID_REG (RFU_STREAM_ID_BASE + 0xC)
	#define USB3H_1_STREAM_ID_REG (RFU_STREAM_ID_BASE + 0x10)
	#define SATA_0_STREAM_ID_REG (RFU_STREAM_ID_BASE + 0x14)
	#define SATA_1_STREAM_ID_REG (RFU_STREAM_ID_BASE + 0x18)

	#define CP_DMA_0_STREAM_ID_REG (0x6B0010)
	#define CP_DMA_1_STREAM_ID_REG (0x6D0010)

	/* We allocate IDs 128-255 for PCIe */
	#define MAX_STREAM_ID (0x80)

	uintptr_t stream_id_reg[] = {
	USB3H_0_STREAM_ID_REG,
	USB3H_1_STREAM_ID_REG,
	CP_DMA_0_STREAM_ID_REG,
	CP_DMA_1_STREAM_ID_REG,
	SATA_0_STREAM_ID_REG,
	SATA_1_STREAM_ID_REG,
	0
	};

	static void cp110_errata_wa_init(uintptr_t base)
	{
	uint32_t data;

	/* ERRATA GL-4076863:
	* Reset value for global_secure_enable inputs must be changed
	* from '1' to '0'.
	* When asserted, only "secured" transactions can enter IHB
	* configuration space.
	* However, blocking AXI transactions is performed by IOB.
	* Performing it also at IHB/HB complicates programming model.
	*
	* Enable non-secure access in SOC configuration register
	*/
	data = mmio_read_32(base + MVEBU_SOC_CFG_REG(MVEBU_SOC_CFG_REG_NUM));
	data &= ~MVEBU_SOC_CFG_GLOG_SECURE_EN_MASK;
	mmio_write_32(base + MVEBU_SOC_CFG_REG(MVEBU_SOC_CFG_REG_NUM), data);
	}

	static void cp110_pcie_clk_cfg(uintptr_t base)
	{
	uint32_t pcie0_clk, pcie1_clk, reg;

	/*
	* Determine the pcie0/1 clock direction (input/output) from the
	* sample at reset.
	*/
	reg = mmio_read_32(base + MVEBU_SAMPLE_AT_RESET_REG);
	pcie0_clk = (reg & SAR_PCIE0_CLK_CFG_MASK) >> SAR_PCIE0_CLK_CFG_OFFSET;
	pcie1_clk = (reg & SAR_PCIE1_CLK_CFG_MASK) >> SAR_PCIE1_CLK_CFG_OFFSET;

	/* CP110 revision A2 */
	if (cp110_rev_id_get(base) == MVEBU_CP110_REF_ID_A2) {
	/*
	* PCIe Reference Clock Buffer Control register must be
	* set according to the clock direction (input/output)
	*/
	reg = mmio_read_32(base + MVEBU_PCIE_REF_CLK_BUF_CTRL);
	reg &= ~(PCIE0_REFCLK_BUFF_SOURCE \| PCIE1_REFCLK_BUFF_SOURCE);
	if (!pcie0_clk)
	reg \|= PCIE0_REFCLK_BUFF_SOURCE;
	if (!pcie1_clk)
	reg \|= PCIE1_REFCLK_BUFF_SOURCE;

	mmio_write_32(base + MVEBU_PCIE_REF_CLK_BUF_CTRL, reg);
	}

	/* CP110 revision A1 */
	if (cp110_rev_id_get(base) == MVEBU_CP110_REF_ID_A1) {
	if (!pcie0_clk \|\| !pcie1_clk) {
	/*
	* if one of the pcie clocks is set to input,
	* we need to set mss_push[131] field, otherwise,
	* the pcie clock might not work.
	*/
	reg = mmio_read_32(base + MVEBU_CP_MSS_DPSHSR_REG);
	reg \|= MSS_DPSHSR_REG_PCIE_CLK_SEL;
	mmio_write_32(base + MVEBU_CP_MSS_DPSHSR_REG, reg);
	}
	}
	}

	/* Set a unique stream id for all DMA capable devices */
	static void cp110_stream_id_init(uintptr_t base, uint32_t stream_id)
	{
	int i = 0;

	while (stream_id_reg[i]) {
	if (i > MAX_STREAM_ID_PER_CP) {
	NOTICE("Only first %d (maximum) Stream IDs allocated\n",
	MAX_STREAM_ID_PER_CP);
	return;
	}

	if ((stream_id_reg[i] == CP_DMA_0_STREAM_ID_REG) \|\|
	(stream_id_reg[i] == CP_DMA_1_STREAM_ID_REG))
	mmio_write_32(base + stream_id_reg[i],
	stream_id << 16 \| stream_id);
	else
	mmio_write_32(base + stream_id_reg[i], stream_id);

	/* SATA port 0/1 are in the same SATA unit, and they should use
	* the same STREAM ID number
	*/
	if (stream_id_reg[i] != SATA_0_STREAM_ID_REG)
	stream_id++;

	i++;
	}
	}

	static void cp110_axi_attr_init(uintptr_t base)
	{
	uint32_t index, data;

	/* Initialize AXI attributes for Armada-7K/8K SoC */

	/* Go over the AXI attributes and set Ax-Cache and Ax-Domain */
	for (index = 0; index < AXI_MAX_ATTR; index++) {
	switch (index) {
	/* DFX and MSS unit works with no coherent only -
	* there's no option to configure the Ax-Cache and Ax-Domain
	*/
	case AXI_DFX_ATTR:
	case AXI_MSS_ATTR:
	continue;
	default:
	/* Set Ax-Cache as cacheable, no allocate, modifiable,
	* bufferable
	* The values are different because Read & Write
	* definition is different in Ax-Cache
	*/
	data = mmio_read_32(base + MVEBU_AXI_ATTR_REG(index));
	data &= ~MVEBU_AXI_ATTR_ARCACHE_MASK;
	data \|= (CACHE_ATTR_WRITE_ALLOC \|
	CACHE_ATTR_CACHEABLE \|
	CACHE_ATTR_BUFFERABLE) <<
	MVEBU_AXI_ATTR_ARCACHE_OFFSET;
	data &= ~MVEBU_AXI_ATTR_AWCACHE_MASK;
	data \|= (CACHE_ATTR_READ_ALLOC \|
	CACHE_ATTR_CACHEABLE \|
	CACHE_ATTR_BUFFERABLE) <<
	MVEBU_AXI_ATTR_AWCACHE_OFFSET;
	/* Set Ax-Domain as Outer domain */
	data &= ~MVEBU_AXI_ATTR_ARDOMAIN_MASK;
	data \|= DOMAIN_OUTER_SHAREABLE <<
	MVEBU_AXI_ATTR_ARDOMAIN_OFFSET;
	data &= ~MVEBU_AXI_ATTR_AWDOMAIN_MASK;
	data \|= DOMAIN_OUTER_SHAREABLE <<
	MVEBU_AXI_ATTR_AWDOMAIN_OFFSET;
	mmio_write_32(base + MVEBU_AXI_ATTR_REG(index), data);
	}
	}

	/* SATA IOCC supported, cache attributes
	* for SATA MBUS to AXI configuration.
	*/
	data = mmio_read_32(base + MVEBU_SATA_M2A_AXI_PORT_CTRL_REG);
	data &= ~MVEBU_SATA_M2A_AXI_AWCACHE_MASK;
	data \|= (CACHE_ATTR_WRITE_ALLOC \|
	CACHE_ATTR_CACHEABLE \|
	CACHE_ATTR_BUFFERABLE) <<
	MVEBU_SATA_M2A_AXI_AWCACHE_OFFSET;
	data &= ~MVEBU_SATA_M2A_AXI_ARCACHE_MASK;
	data \|= (CACHE_ATTR_READ_ALLOC \|
	CACHE_ATTR_CACHEABLE \|
	CACHE_ATTR_BUFFERABLE) <<
	MVEBU_SATA_M2A_AXI_ARCACHE_OFFSET;
	mmio_write_32(base + MVEBU_SATA_M2A_AXI_PORT_CTRL_REG, data);

	/* Set all IO's AXI attribute to non-secure access. */
	for (index = 0; index < MVEBU_AXI_PROT_REGS_NUM; index++)
	mmio_write_32(base + MVEBU_AXI_PROT_REG(index),
	DOMAIN_SYSTEM_SHAREABLE);
	}

	static void amb_bridge_init(uintptr_t base)
	{
	uint32_t reg;

	/* Open AMB bridge Window to Access COMPHY/MDIO registers */
	reg = mmio_read_32(base + MVEBU_AMB_IP_BRIDGE_WIN_REG(0));
	reg &= ~(MVEBU_AMB_IP_BRIDGE_WIN_SIZE_MASK \|
	MVEBU_AMB_IP_BRIDGE_WIN_EN_MASK);
	reg \|= (0x7ff << MVEBU_AMB_IP_BRIDGE_WIN_SIZE_OFFSET) \|
	(0x1 << MVEBU_AMB_IP_BRIDGE_WIN_EN_OFFSET);
	mmio_write_32(base + MVEBU_AMB_IP_BRIDGE_WIN_REG(0), reg);
	}

	static void cp110_rtc_init(uintptr_t base)
	{
	/* Update MBus timing parameters before accessing RTC registers */
	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG,
	MVEBU_RTC_WRCLK_PERIOD_MASK,
	MVEBU_RTC_WRCLK_PERIOD_DEFAULT);

	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL0_REG,
	MVEBU_RTC_WRCLK_SETUP_MASK,
	MVEBU_RTC_WRCLK_SETUP_DEFAULT <<
	MVEBU_RTC_WRCLK_SETUP_OFFS);

	mmio_clrsetbits_32(base + MVEBU_RTC_BRIDGE_TIMING_CTRL1_REG,
	MVEBU_RTC_READ_OUTPUT_DELAY_MASK,
	MVEBU_RTC_READ_OUTPUT_DELAY_DEFAULT);

	/*
	* Issue reset to the RTC if Clock Correction register
	* contents did not sustain the reboot/power-on.
	*/
	if ((mmio_read_32(base + MVEBU_RTC_CCR_REG) &
	MVEBU_RTC_NOMINAL_TIMING_MASK) != MVEBU_RTC_NOMINAL_TIMING) {
	/* Reset Test register */
	mmio_write_32(base + MVEBU_RTC_TEST_CONFIG_REG, 0);
	mdelay(500);

	/* Reset Status register */
	mmio_write_32(base + MVEBU_RTC_STATUS_REG,
	(MVEBU_RTC_STATUS_ALARM1_MASK \|
	MVEBU_RTC_STATUS_ALARM2_MASK));
	udelay(62);

	/* Turn off Int1 and Int2 sources & clear the Alarm count */
	mmio_write_32(base + MVEBU_RTC_IRQ_1_CONFIG_REG, 0);
	mmio_write_32(base + MVEBU_RTC_IRQ_2_CONFIG_REG, 0);
	mmio_write_32(base + MVEBU_RTC_ALARM_1_REG, 0);
	mmio_write_32(base + MVEBU_RTC_ALARM_2_REG, 0);

	/* Setup nominal register access timing */
	mmio_write_32(base + MVEBU_RTC_CCR_REG,
	MVEBU_RTC_NOMINAL_TIMING);

	/* Reset Status register */
	mmio_write_32(base + MVEBU_RTC_STATUS_REG,
	(MVEBU_RTC_STATUS_ALARM1_MASK \|
	MVEBU_RTC_STATUS_ALARM2_MASK));
	udelay(50);
	}
	}

	static void cp110_amb_adec_init(uintptr_t base)
	{
	/* enable AXI-MBUS by clearing "Bridge Windows Disable" */
	mmio_clrbits_32(base + MVEBU_BRIDGE_WIN_DIS_REG,
	(1 << MVEBU_BRIDGE_WIN_DIS_OFF));

	/* configure AXI-MBUS windows for CP */
	init_amb_adec(base);
	}

	void cp110_init(uintptr_t cp110_base, uint32_t stream_id)
	{
	INFO("%s: Initialize CPx - base = %lx\n", __func__, cp110_base);

	/* configure IOB windows for CP0*/
	init_iob(cp110_base);

	/* configure AXI-MBUS windows for CP0*/
	cp110_amb_adec_init(cp110_base);

	/* configure axi for CP0*/
	cp110_axi_attr_init(cp110_base);

	/* Execute SW WA for erratas */
	cp110_errata_wa_init(cp110_base);

	/* Confiure pcie clock according to clock direction */
	cp110_pcie_clk_cfg(cp110_base);

	/* configure stream id for CP0 */
	cp110_stream_id_init(cp110_base, stream_id);

	/* Open AMB bridge for comphy for CP0 & CP1*/
	amb_bridge_init(cp110_base);

	/* Reset RTC if needed */
	cp110_rtc_init(cp110_base);
	}

	/* Do the minimal setup required to configure the CP in BLE */
	void cp110_ble_init(uintptr_t cp110_base)
	{
	#if PCI_EP_SUPPORT
	INFO("%s: Initialize CPx - base = %lx\n", __func__, cp110_base);

	amb_bridge_init(cp110_base);

	/* Configure PCIe clock */
	cp110_pcie_clk_cfg(cp110_base);

	/* Configure PCIe endpoint */
	ble_plat_pcie_ep_setup();
	#endif
	}