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coral / tf-a-mtk / ee006a79f622b39a35beaaf95d7b42b7078823f8 / . / drivers / marvell / mci.c
blob: 06fe88e13adc2ac2a70b4bf71662578958695124 [file] [log] [blame]
/*
* Copyright (C) 2018 Marvell International Ltd.
*
* SPDX-License-Identifier: BSD-3-Clause
* https://spdx.org/licenses
*/
/* MCI bus driver for Marvell ARMADA 8K and 8K+ SoCs */
#include <common/debug.h>
#include <drivers/delay_timer.h>
#include <drivers/marvell/mci.h>
#include <lib/mmio.h>
#include <mvebu.h>
#include <mvebu_def.h>
#include <plat_marvell.h>
/* /HB /Units /Direct_regs /Direct regs
* /Configuration Register Write/Read Data Register
*/
#define MCI_WRITE_READ_DATA_REG(mci_index) \
MVEBU_MCI_REG_BASE_REMAP(mci_index)
/* /HB /Units /Direct_regs /Direct regs
* /Configuration Register Access Command Register
*/
#define MCI_ACCESS_CMD_REG(mci_index) \
(MVEBU_MCI_REG_BASE_REMAP(mci_index) + 0x4)
/* Access Command fields :
* bit[3:0] - Sub command: 1 => Peripheral Config Register Read,
* 0 => Peripheral Config Register Write,
* 2 => Peripheral Assign ID request,
* 3 => Circular Config Write
* bit[5] - 1 => Local (same chip access) 0 => Remote
* bit[15:8] - Destination hop ID. Put Global ID (GID) here (see scheme below).
* bit[23:22] - 0x3 IHB PHY REG address space, 0x0 IHB Controller space
* bit[21:16] - Low 6 bits of offset. Hight 2 bits are taken from bit[28:27]
* of IHB_PHY_CTRL
* (must be set before any PHY register access occurs):
* /IHB_REG /IHB_REGInterchip Hopping Bus Registers
* /IHB Version Control Register
*
* ixi_ihb_top IHB PHY
* AXI ----------------------------- -------------
* <--| axi_hb_top | ihb_pipe_top |-->| |
* -->| GID=1 | GID=0 |<--| |
* ----------------------------- -------------
*/
#define MCI_INDIRECT_CTRL_READ_CMD 0x1
#define MCI_INDIRECT_CTRL_ASSIGN_CMD 0x2
#define MCI_INDIRECT_CTRL_CIRCULAR_CMD 0x3
#define MCI_INDIRECT_CTRL_LOCAL_PKT (1 << 5)
#define MCI_INDIRECT_CTRL_CMD_DONE_OFFSET 6
#define MCI_INDIRECT_CTRL_CMD_DONE \
(1 << MCI_INDIRECT_CTRL_CMD_DONE_OFFSET)
#define MCI_INDIRECT_CTRL_DATA_READY_OFFSET 7
#define MCI_INDIRECT_CTRL_DATA_READY \
(1 << MCI_INDIRECT_CTRL_DATA_READY_OFFSET)
#define MCI_INDIRECT_CTRL_HOPID_OFFSET 8
#define MCI_INDIRECT_CTRL_HOPID(id) \
(((id) & 0xFF) << MCI_INDIRECT_CTRL_HOPID_OFFSET)
#define MCI_INDIRECT_CTRL_REG_CHIPID_OFFSET 16
#define MCI_INDIRECT_REG_CTRL_ADDR(reg_num) \
(reg_num << MCI_INDIRECT_CTRL_REG_CHIPID_OFFSET)
/* Hop ID values */
#define GID_IHB_PIPE 0
#define GID_AXI_HB 1
#define GID_IHB_EXT 2
#define MCI_DID_GLOBAL_ASSIGNMENT_REQUEST_REG 0x2
/* Target MCi Local ID (LID, which is = self DID) */
#define MCI_DID_GLOBAL_ASSIGN_REQ_MCI_LOCAL_ID(val) (((val) & 0xFF) << 16)
/* Bits [15:8]: Number of MCis on chip of target MCi */
#define MCI_DID_GLOBAL_ASSIGN_REQ_MCI_COUNT(val) (((val) & 0xFF) << 8)
/* Bits [7:0]: Number of hops on chip of target MCi */
#define MCI_DID_GLOBAL_ASSIGN_REQ_HOPS_NUM(val) (((val) & 0xFF) << 0)
/* IHB_REG domain registers */
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers/
* Rx Memory Configuration Register (RX_MEM_CFG)
*/
#define MCI_CTRL_RX_MEM_CFG_REG_NUM 0x0
#define MCI_CTRL_RX_TX_MEM_CFG_RQ_THRESH(val) (((val) & 0xFF) << 24)
#define MCI_CTRL_RX_TX_MEM_CFG_PQ_THRESH(val) (((val) & 0xFF) << 16)
#define MCI_CTRL_RX_TX_MEM_CFG_NQ_THRESH(val) (((val) & 0xFF) << 8)
#define MCI_CTRL_RX_TX_MEM_CFG_DELTA_THRESH(val) (((val) & 0xF) << 4)
#define MCI_CTRL_RX_TX_MEM_CFG_RTC(val) (((val) & 0x3) << 2)
#define MCI_CTRL_RX_TX_MEM_CFG_WTC(val) (((val) & 0x3) << 0)
#define MCI_CTRL_RX_MEM_CFG_REG_DEF_CP_VAL \
(MCI_CTRL_RX_TX_MEM_CFG_RQ_THRESH(0x07) | \
MCI_CTRL_RX_TX_MEM_CFG_PQ_THRESH(0x3f) | \
MCI_CTRL_RX_TX_MEM_CFG_NQ_THRESH(0x3f) | \
MCI_CTRL_RX_TX_MEM_CFG_DELTA_THRESH(0xf) | \
MCI_CTRL_RX_TX_MEM_CFG_RTC(1) | \
MCI_CTRL_RX_TX_MEM_CFG_WTC(1))
#define MCI_CTRL_RX_MEM_CFG_REG_DEF_AP_VAL \
(MCI_CTRL_RX_TX_MEM_CFG_RQ_THRESH(0x3f) | \
MCI_CTRL_RX_TX_MEM_CFG_PQ_THRESH(0x03) | \
MCI_CTRL_RX_TX_MEM_CFG_NQ_THRESH(0x3f) | \
MCI_CTRL_RX_TX_MEM_CFG_DELTA_THRESH(0xf) | \
MCI_CTRL_RX_TX_MEM_CFG_RTC(1) | \
MCI_CTRL_RX_TX_MEM_CFG_WTC(1))
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers/
* Tx Memory Configuration Register (TX_MEM_CFG)
*/
#define MCI_CTRL_TX_MEM_CFG_REG_NUM 0x1
/* field mapping for TX mem config register
* are the same as for RX register - see register above
*/
#define MCI_CTRL_TX_MEM_CFG_REG_DEF_VAL \
(MCI_CTRL_RX_TX_MEM_CFG_RQ_THRESH(0x20) | \
MCI_CTRL_RX_TX_MEM_CFG_PQ_THRESH(0x20) | \
MCI_CTRL_RX_TX_MEM_CFG_NQ_THRESH(0x20) | \
MCI_CTRL_RX_TX_MEM_CFG_DELTA_THRESH(2) | \
MCI_CTRL_RX_TX_MEM_CFG_RTC(1) | \
MCI_CTRL_RX_TX_MEM_CFG_WTC(1))
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers
* /IHB Link CRC Control
*/
/* MCi Link CRC Control Register (MCi_CRC_CTRL) */
#define MCI_LINK_CRC_CTRL_REG_NUM 0x4
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers
* /IHB Status Register
*/
/* MCi Status Register (MCi_STS) */
#define MCI_CTRL_STATUS_REG_NUM 0x5
#define MCI_CTRL_STATUS_REG_PHY_READY (1 << 12)
#define MCI_CTRL_STATUS_REG_LINK_PRESENT (1 << 15)
#define MCI_CTRL_STATUS_REG_PHY_CID_VIO_OFFSET 24
#define MCI_CTRL_STATUS_REG_PHY_CID_VIO_MASK \
(0xF << MCI_CTRL_STATUS_REG_PHY_CID_VIO_OFFSET)
/* Expected successful Link result, including reserved bit */
#define MCI_CTRL_PHY_READY (MCI_CTRL_STATUS_REG_PHY_READY | \
MCI_CTRL_STATUS_REG_LINK_PRESENT | \
MCI_CTRL_STATUS_REG_PHY_CID_VIO_MASK)
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers/
* MCi PHY Speed Settings Register (MCi_PHY_SETTING)
*/
#define MCI_CTRL_MCI_PHY_SETTINGS_REG_NUM 0x8
#define MCI_CTRL_MCI_PHY_SET_DLO_FIFO_FULL_TRESH(val) (((val) & 0xF) << 28)
#define MCI_CTRL_MCI_PHY_SET_PHY_MAX_SPEED(val) (((val) & 0xF) << 12)
#define MCI_CTRL_MCI_PHY_SET_PHYCLK_SEL(val) (((val) & 0xF) << 8)
#define MCI_CTRL_MCI_PHY_SET_REFCLK_FREQ_SEL(val) (((val) & 0xF) << 4)
#define MCI_CTRL_MCI_PHY_SET_AUTO_LINK_EN(val) (((val) & 0x1) << 1)
#define MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL \
(MCI_CTRL_MCI_PHY_SET_DLO_FIFO_FULL_TRESH(0x3) | \
MCI_CTRL_MCI_PHY_SET_PHY_MAX_SPEED(0x3) | \
MCI_CTRL_MCI_PHY_SET_PHYCLK_SEL(0x2) | \
MCI_CTRL_MCI_PHY_SET_REFCLK_FREQ_SEL(0x1))
#define MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL2 \
(MCI_CTRL_MCI_PHY_SET_DLO_FIFO_FULL_TRESH(0x3) | \
MCI_CTRL_MCI_PHY_SET_PHY_MAX_SPEED(0x3) | \
MCI_CTRL_MCI_PHY_SET_PHYCLK_SEL(0x5) | \
MCI_CTRL_MCI_PHY_SET_REFCLK_FREQ_SEL(0x1))
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers
* /IHB Mode Config
*/
#define MCI_CTRL_IHB_MODE_CFG_REG_NUM 0x25
#define MCI_CTRL_IHB_MODE_HBCLK_DIV(val) ((val) & 0xFF)
#define MCI_CTRL_IHB_MODE_CHUNK_MOD_OFFSET 8
#define MCI_CTRL_IHB_MODE_CHUNK_MOD \
(1 << MCI_CTRL_IHB_MODE_CHUNK_MOD_OFFSET)
#define MCI_CTRL_IHB_MODE_FWD_MOD_OFFSET 9
#define MCI_CTRL_IHB_MODE_FWD_MOD \
(1 << MCI_CTRL_IHB_MODE_FWD_MOD_OFFSET)
#define MCI_CTRL_IHB_MODE_SEQFF_FINE_MOD(val) (((val) & 0xF) << 12)
#define MCI_CTRL_IHB_MODE_RX_COMB_THRESH(val) (((val) & 0xFF) << 16)
#define MCI_CTRL_IHB_MODE_TX_COMB_THRESH(val) (((val) & 0xFF) << 24)
#define MCI_CTRL_IHB_MODE_CFG_REG_DEF_VAL \
(MCI_CTRL_IHB_MODE_HBCLK_DIV(6) | \
MCI_CTRL_IHB_MODE_FWD_MOD | \
MCI_CTRL_IHB_MODE_SEQFF_FINE_MOD(0xF) | \
MCI_CTRL_IHB_MODE_RX_COMB_THRESH(0x3f) | \
MCI_CTRL_IHB_MODE_TX_COMB_THRESH(0x40))
/* AXI_HB registers */
#define MCI_AXI_ACCESS_DATA_REG_NUM 0x0
#define MCI_AXI_ACCESS_PCIE_MODE 1
#define MCI_AXI_ACCESS_CACHE_CHECK_OFFSET 5
#define MCI_AXI_ACCESS_CACHE_CHECK \
(1 << MCI_AXI_ACCESS_CACHE_CHECK_OFFSET)
#define MCI_AXI_ACCESS_FORCE_POST_WR_OFFSET 6
#define MCI_AXI_ACCESS_FORCE_POST_WR \
(1 << MCI_AXI_ACCESS_FORCE_POST_WR_OFFSET)
#define MCI_AXI_ACCESS_DISABLE_CLK_GATING_OFFSET 9
#define MCI_AXI_ACCESS_DISABLE_CLK_GATING \
(1 << MCI_AXI_ACCESS_DISABLE_CLK_GATING_OFFSET)
/* /HB /Units /HB_REG /HB_REGHopping Bus Registers
* /Window 0 Address Mask Register
*/
#define MCI_HB_CTRL_WIN0_ADDRESS_MASK_REG_NUM 0x2
/* /HB /Units /HB_REG /HB_REGHopping Bus Registers
* /Window 0 Destination Register
*/
#define MCI_HB_CTRL_WIN0_DESTINATION_REG_NUM 0x3
#define MCI_HB_CTRL_WIN0_DEST_VALID_FLAG(val) (((val) & 0x1) << 16)
#define MCI_HB_CTRL_WIN0_DEST_ID(val) (((val) & 0xFF) << 0)
/* /HB /Units /HB_REG /HB_REGHopping Bus Registers /Tx Control Register */
#define MCI_HB_CTRL_TX_CTRL_REG_NUM 0xD
#define MCI_HB_CTRL_TX_CTRL_PCIE_MODE_OFFSET 24
#define MCI_HB_CTRL_TX_CTRL_PCIE_MODE \
(1 << MCI_HB_CTRL_TX_CTRL_PCIE_MODE_OFFSET)
#define MCI_HB_CTRL_TX_CTRL_PRI_TH_QOS(val) (((val) & 0xF) << 12)
#define MCI_HB_CTRL_TX_CTRL_MAX_RD_CNT(val) (((val) & 0x1F) << 6)
#define MCI_HB_CTRL_TX_CTRL_MAX_WR_CNT(val) (((val) & 0x1F) << 0)
/* /HB /Units /IHB_REG /IHB_REGInterchip Hopping Bus Registers
* /IHB Version Control Register
*/
#define MCI_PHY_CTRL_REG_NUM 0x7
#define MCI_PHY_CTRL_MCI_MINOR 0x8 /* BITS [3:0] */
#define MCI_PHY_CTRL_MCI_MAJOR_OFFSET 4
#define MCI_PHY_CTRL_MCI_MAJOR \
(1 << MCI_PHY_CTRL_MCI_MAJOR_OFFSET)
#define MCI_PHY_CTRL_MCI_SLEEP_REQ_OFFSET 11
#define MCI_PHY_CTRL_MCI_SLEEP_REQ \
(1 << MCI_PHY_CTRL_MCI_SLEEP_REQ_OFFSET)
/* Host=1 / Device=0 PHY mode */
#define MCI_PHY_CTRL_MCI_PHY_MODE_OFFSET 24
#define MCI_PHY_CTRL_MCI_PHY_MODE_HOST \
(1 << MCI_PHY_CTRL_MCI_PHY_MODE_OFFSET)
/* Register=1 / PWM=0 interface */
#define MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE_OFFSET 25
#define MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE \
(1 << MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE_OFFSET)
/* PHY code InReset=1 */
#define MCI_PHY_CTRL_MCI_PHY_RESET_CORE_OFFSET 26
#define MCI_PHY_CTRL_MCI_PHY_RESET_CORE \
(1 << MCI_PHY_CTRL_MCI_PHY_RESET_CORE_OFFSET)
#define MCI_PHY_CTRL_PHY_ADDR_MSB_OFFSET 27
#define MCI_PHY_CTRL_PHY_ADDR_MSB(addr) \
(((addr) & 0x3) << \
MCI_PHY_CTRL_PHY_ADDR_MSB_OFFSET)
#define MCI_PHY_CTRL_PIDI_MODE_OFFSET 31
#define MCI_PHY_CTRL_PIDI_MODE \
(1U << MCI_PHY_CTRL_PIDI_MODE_OFFSET)
/* Number of times to wait for the MCI link ready after MCI configurations
* Normally takes 34-35 successive reads
*/
#define LINK_READY_TIMEOUT 100
enum mci_register_type {
MCI_REG_TYPE_PHY = 0,
MCI_REG_TYPE_CTRL,
};
enum {
MCI_CMD_WRITE,
MCI_CMD_READ
};
/* Write wrapper callback for debug:
* will print written data in case LOG_LEVEL >= 40
*/
static void mci_mmio_write_32(uintptr_t addr, uint32_t value)
{
VERBOSE("Write:\t0x%x = 0x%x\n", (uint32_t)addr, value);
mmio_write_32(addr, value);
}
/* Read wrapper callback for debug:
* will print read data in case LOG_LEVEL >= 40
*/
static uint32_t mci_mmio_read_32(uintptr_t addr)
{
uint32_t value;
value = mmio_read_32(addr);
VERBOSE("Read:\t0x%x = 0x%x\n", (uint32_t)addr, value);
return value;
}
/* MCI indirect access command completion polling:
* Each write/read command done via MCI indirect registers must be polled
* for command completions status.
*
* Returns 1 in case of error
* Returns 0 in case of command completed successfully.
*/
static int mci_poll_command_completion(int mci_index, int command_type)
{
uint32_t mci_cmd_value = 0, retry_count = 100, ret = 0;
uint32_t completion_flags = MCI_INDIRECT_CTRL_CMD_DONE;
debug_enter();
/* Read commands require validating that requested data is ready */
if (command_type == MCI_CMD_READ)
completion_flags |= MCI_INDIRECT_CTRL_DATA_READY;
do {
/* wait 1 ms before each polling */
mdelay(1);
mci_cmd_value = mci_mmio_read_32(MCI_ACCESS_CMD_REG(mci_index));
} while (((mci_cmd_value & completion_flags) != completion_flags) &&
(retry_count-- > 0));
if (retry_count == 0) {
ERROR("%s: MCI command timeout (command status = 0x%x)\n",
__func__, mci_cmd_value);
ret = 1;
}
debug_exit();
return ret;
}
int mci_read(int mci_idx, uint32_t cmd, uint32_t *value)
{
int rval;
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_idx), cmd);
rval = mci_poll_command_completion(mci_idx, MCI_CMD_READ);
*value = mci_mmio_read_32(MCI_WRITE_READ_DATA_REG(mci_idx));
return rval;
}
int mci_write(int mci_idx, uint32_t cmd, uint32_t data)
{
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_idx), data);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_idx), cmd);
return mci_poll_command_completion(mci_idx, MCI_CMD_WRITE);
}
/* Perform 3 configurations in one command: PCI mode,
* queues separation and cache bit
*/
static int mci_axi_set_pcie_mode(int mci_index)
{
uint32_t reg_data, ret = 1;
debug_enter();
/* This configuration makes MCI IP behave consistently with AXI protocol
* It should be configured at one side only (for example locally at AP).
* The IP takes care of performing the same configurations at MCI on
* another side (for example remotely at CP).
*/
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_AXI_ACCESS_PCIE_MODE |
MCI_AXI_ACCESS_CACHE_CHECK |
MCI_AXI_ACCESS_FORCE_POST_WR |
MCI_AXI_ACCESS_DISABLE_CLK_GATING);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_AXI_ACCESS_DATA_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT |
MCI_INDIRECT_CTRL_CIRCULAR_CMD);
/* if Write command was successful, verify PCIe mode */
if (mci_poll_command_completion(mci_index, MCI_CMD_WRITE) == 0) {
/* Verify the PCIe mode selected */
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_TX_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT |
MCI_INDIRECT_CTRL_READ_CMD);
/* if read was completed, verify PCIe mode */
if (mci_poll_command_completion(mci_index, MCI_CMD_READ) == 0) {
reg_data = mci_mmio_read_32(
MCI_WRITE_READ_DATA_REG(mci_index));
if (reg_data & MCI_HB_CTRL_TX_CTRL_PCIE_MODE)
ret = 0;
}
}
debug_exit();
return ret;
}
/* Reduce sequence FIFO timer expiration threshold */
static int mci_axi_set_fifo_thresh(int mci_index)
{
uint32_t reg_data, ret = 0;
debug_enter();
/* This configuration reduces sequence FIFO timer expiration threshold
* (to 0x7 instead of 0xA).
* In MCI 1.6 version this configuration prevents possible functional
* issues.
* In version 1.82 the configuration prevents performance degradation
*/
/* Configure local AP side */
reg_data = MCI_PHY_CTRL_PIDI_MODE |
MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE |
MCI_PHY_CTRL_MCI_PHY_MODE_HOST |
MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_MINOR;
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index), reg_data);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Reduce the threshold */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_IHB_MODE_CFG_REG_DEF_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_IHB_MODE_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Exit PIDI mode */
reg_data = MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE |
MCI_PHY_CTRL_MCI_PHY_MODE_HOST |
MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_MINOR;
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index), reg_data);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Configure remote CP side */
reg_data = MCI_PHY_CTRL_PIDI_MODE |
MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_MINOR |
MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE;
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index), reg_data);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_CTRL_IHB_MODE_FWD_MOD);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Reduce the threshold */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_IHB_MODE_CFG_REG_DEF_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_IHB_MODE_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Exit PIDI mode */
reg_data = MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_MINOR |
MCI_PHY_CTRL_MCI_PHY_REG_IF_MODE;
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index), reg_data);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_CTRL_IHB_MODE_FWD_MOD);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
debug_exit();
return ret;
}
/* Configure:
* 1. AP & CP TX thresholds and delta configurations
* 2. DLO & DLI FIFO full threshold
* 3. RX thresholds and delta configurations
* 4. CP AR and AW outstanding
* 5. AP AR and AW outstanding
*/
static int mci_axi_set_fifo_rx_tx_thresh(int mci_index)
{
uint32_t ret = 0;
debug_enter();
/* AP TX thresholds and delta configurations (IHB_reg 0x1) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_TX_MEM_CFG_REG_DEF_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_TX_MEM_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* CP TX thresholds and delta configurations (IHB_reg 0x1) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_TX_MEM_CFG_REG_DEF_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_TX_MEM_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* AP DLO & DLI FIFO full threshold & Auto-Link enable (IHB_reg 0x8) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL |
MCI_CTRL_MCI_PHY_SET_AUTO_LINK_EN(1));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_MCI_PHY_SETTINGS_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* CP DLO & DLI FIFO full threshold (IHB_reg 0x8) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_MCI_PHY_SETTINGS_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* AP RX thresholds and delta configurations (IHB_reg 0x0) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_RX_MEM_CFG_REG_DEF_AP_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_RX_MEM_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* CP RX thresholds and delta configurations (IHB_reg 0x0) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_CTRL_RX_MEM_CFG_REG_DEF_CP_VAL);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_CTRL_RX_MEM_CFG_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* AP AR & AW maximum AXI outstanding request cfg (HB_reg 0xd) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_HB_CTRL_TX_CTRL_PRI_TH_QOS(8) |
MCI_HB_CTRL_TX_CTRL_MAX_RD_CNT(3) |
MCI_HB_CTRL_TX_CTRL_MAX_WR_CNT(3));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_TX_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* CP AR & AW maximum AXI outstanding request cfg (HB_reg 0xd) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(mci_index),
MCI_HB_CTRL_TX_CTRL_PRI_TH_QOS(8) |
MCI_HB_CTRL_TX_CTRL_MAX_RD_CNT(0xB) |
MCI_HB_CTRL_TX_CTRL_MAX_WR_CNT(0x11));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(mci_index),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_TX_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
debug_exit();
return ret;
}
/* configure MCI to allow read & write transactions to arrive at the same time.
* Without the below configuration, MCI won't sent response to CPU for
* transactions which arrived simultaneously and will lead to CPU hang.
* The below will configure MCI to be able to pass transactions from/to CP/AP.
*/
static int mci_enable_simultaneous_transactions(int mci_index)
{
uint32_t ret = 0;
debug_enter();
/* ID assignment (assigning global ID offset to CP) */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(0),
MCI_DID_GLOBAL_ASSIGN_REQ_MCI_LOCAL_ID(2) |
MCI_DID_GLOBAL_ASSIGN_REQ_MCI_COUNT(2) |
MCI_DID_GLOBAL_ASSIGN_REQ_HOPS_NUM(2));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_DID_GLOBAL_ASSIGNMENT_REQUEST_REG) |
MCI_INDIRECT_CTRL_ASSIGN_CMD);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Assigning dest. ID=3 to all transactions entering from AXI at AP */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(0),
MCI_HB_CTRL_WIN0_DEST_VALID_FLAG(1) |
MCI_HB_CTRL_WIN0_DEST_ID(3));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_WIN0_DESTINATION_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* Assigning dest. ID=1 to all transactions entering from AXI at CP */
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(0),
MCI_HB_CTRL_WIN0_DEST_VALID_FLAG(1) |
MCI_HB_CTRL_WIN0_DEST_ID(1));
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_WIN0_DESTINATION_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* End address to all transactions entering from AXI at AP.
* This will lead to get match for any AXI address
* and receive destination ID=3
*/
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(0), 0xffffffff);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_WIN0_ADDRESS_MASK_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
/* End address to all transactions entering from AXI at CP.
* This will lead to get match for any AXI address
* and receive destination ID=1
*/
mci_mmio_write_32(MCI_WRITE_READ_DATA_REG(0), 0xffffffff);
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_WIN0_ADDRESS_MASK_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_IHB_EXT) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB));
ret |= mci_poll_command_completion(mci_index, MCI_CMD_WRITE);
debug_exit();
return ret;
}
/* Check if MCI simultaneous transaction was already enabled.
* Currently bootrom does this mci configuration only when the boot source is
* SAR_MCIX4, in other cases it should be done at this stage.
* It is worth noticing that in case of booting from uart, the bootrom
* flow is different and this mci initialization is skipped even if boot
* source is SAR_MCIX4. Therefore new verification bases on appropriate mci's
* register content: if the appropriate reg contains 0x0 it means that the
* bootrom didn't perform required mci configuration.
*
* Returns:
* 0 - configuration already done
* 1 - configuration missing
*/
static _Bool mci_simulatenous_trans_missing(int mci_index)
{
uint32_t reg, ret;
/* read 'Window 0 Destination ID assignment' from HB register 0x3
* (TX_CFG_W0_DST_ID) to check whether ID assignment was already
* performed by BootROM.
*/
debug_enter();
mci_mmio_write_32(MCI_ACCESS_CMD_REG(0),
MCI_INDIRECT_REG_CTRL_ADDR(
MCI_HB_CTRL_WIN0_DESTINATION_REG_NUM) |
MCI_INDIRECT_CTRL_HOPID(GID_AXI_HB) |
MCI_INDIRECT_CTRL_LOCAL_PKT |
MCI_INDIRECT_CTRL_READ_CMD);
ret = mci_poll_command_completion(mci_index, MCI_CMD_READ);
reg = mci_mmio_read_32(MCI_WRITE_READ_DATA_REG(mci_index));
if (ret)
ERROR("Failed to verify MCI simultaneous read/write status\n");
debug_exit();
/* default ID assignment is 0, so if register doesn't contain zeros
* it means that bootrom already performed required configuration.
*/
if (reg != 0)
return 0;
return 1;
}
/* For A1 revision, configure the MCI link for performance improvement:
* - set MCI to support read/write transactions to arrive at the same time
* - Switch AXI to PCIe mode
* - Reduce sequence FIFO threshold
* - Configure RX/TX FIFO thresholds
*
* Note:
* We don't exit on error code from any sub routine, to try (best effort) to
* complete the MCI configuration.
* (If we exit - Bootloader will surely fail to boot)
*/
int mci_configure(int mci_index)
{
int rval;
debug_enter();
/* According to design guidelines the MCI simultaneous transaction
* shouldn't be enabled more then once - therefore make sure that it
* wasn't already enabled in bootrom.
*/
if (mci_simulatenous_trans_missing(mci_index)) {
VERBOSE("Enabling MCI simultaneous transaction\n");
/* set MCI to support read/write transactions
* to arrive at the same time
*/
rval = mci_enable_simultaneous_transactions(mci_index);
if (rval)
ERROR("Failed to set MCI simultaneous read/write\n");
} else
VERBOSE("Skip MCI ID assignment - already done by bootrom\n");
/* Configure MCI for more consistent behavior with AXI protocol */
rval = mci_axi_set_pcie_mode(mci_index);
if (rval)
ERROR("Failed to set MCI to AXI PCIe mode\n");
/* reduce FIFO global threshold */
rval = mci_axi_set_fifo_thresh(mci_index);
if (rval)
ERROR("Failed to set MCI FIFO global threshold\n");
/* configure RX/TX FIFO thresholds */
rval = mci_axi_set_fifo_rx_tx_thresh(mci_index);
if (rval)
ERROR("Failed to set MCI RX/TX FIFO threshold\n");
debug_exit();
return 1;
}
int mci_get_link_status(void)
{
uint32_t cmd, data;
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_CTRL_STATUS_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT | MCI_INDIRECT_CTRL_READ_CMD);
if (mci_read(0, cmd, &data)) {
ERROR("Failed to read status register\n");
return -1;
}
/* Check if the link is ready */
if (data != MCI_CTRL_PHY_READY) {
ERROR("Bad link status %x\n", data);
return -1;
}
return 0;
}
void mci_turn_link_down(void)
{
uint32_t cmd, data;
int rval = 0;
debug_enter();
/* Turn off auto-link */
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_CTRL_MCI_PHY_SETTINGS_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = (MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL2 |
MCI_CTRL_MCI_PHY_SET_AUTO_LINK_EN(0));
rval = mci_write(0, cmd, data);
if (rval)
ERROR("Failed to turn off auto-link\n");
/* Reset AP PHY */
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = (MCI_PHY_CTRL_MCI_MINOR |
MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_PHY_MODE_HOST |
MCI_PHY_CTRL_MCI_PHY_RESET_CORE);
rval = mci_write(0, cmd, data);
if (rval)
ERROR("Failed to reset AP PHY\n");
/* Clear all status & CRC values */
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_LINK_CRC_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = 0x0;
mci_write(0, cmd, data);
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_CTRL_STATUS_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = 0x0;
rval = mci_write(0, cmd, data);
if (rval)
ERROR("Failed to reset AP PHY\n");
/* Wait 5ms before un-reset the PHY */
mdelay(5);
/* Un-reset AP PHY */
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_PHY_CTRL_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = (MCI_PHY_CTRL_MCI_MINOR | MCI_PHY_CTRL_MCI_MAJOR |
MCI_PHY_CTRL_MCI_PHY_MODE_HOST);
rval = mci_write(0, cmd, data);
if (rval)
ERROR("Failed to un-reset AP PHY\n");
debug_exit();
}
void mci_turn_link_on(void)
{
uint32_t cmd, data;
int rval = 0;
debug_enter();
/* Turn on auto-link */
cmd = (MCI_INDIRECT_REG_CTRL_ADDR(MCI_CTRL_MCI_PHY_SETTINGS_REG_NUM) |
MCI_INDIRECT_CTRL_LOCAL_PKT);
data = (MCI_CTRL_MCI_PHY_SET_REG_DEF_VAL2 |
MCI_CTRL_MCI_PHY_SET_AUTO_LINK_EN(1));
rval = mci_write(0, cmd, data);
if (rval)
ERROR("Failed to turn on auto-link\n");
debug_exit();
}
/* Initialize MCI for performance improvements */
int mci_initialize(int mci_index)
{
int ret;
debug_enter();
INFO("MCI%d initialization:\n", mci_index);
ret = mci_configure(mci_index);
debug_exit();
return ret;
}