#include "ice_common.h"
#include "ice_ptp_hw.h"
+#include "ice_ptp_consts.h"
/* Low level functions for interacting with and managing the device clock used
* for the Precision Time Protocol.
*
* For E810 devices, the increment frequency is 812.5 MHz
*
+ * For E822 devices the clock can be derived from different sources, and the
+ * increment has an effective frequency of one of the following:
+ * - 823.4375 MHz
+ * - 783.36 MHz
+ * - 796.875 MHz
+ * - 816 MHz
+ * - 830.078125 MHz
+ * - 783.36 MHz
+ *
* The hardware captures timestamps in the PHY for incoming packets, and for
* outgoing packets on request. To support this, the PHY maintains a timer
* that matches the lower 64 bits of the global source timer.
*
- * In order to ensure that the PHY timers and the source timer are equivalent,
- * shadow registers are used to prepare the desired initial values. A special
- * sync command is issued to trigger copying from the shadow registers into
- * the appropriate source and PHY registers simultaneously.
+ * In order to ensure that the PHY timers and the source timer are equivalent,
+ * shadow registers are used to prepare the desired initial values. A special
+ * sync command is issued to trigger copying from the shadow registers into
+ * the appropriate source and PHY registers simultaneously.
+ *
+ * The driver supports devices which have different PHYs with subtly different
+ * mechanisms to program and control the timers. We divide the devices into
+ * families named after the first major device, E810 and similar devices, and
+ * E822 and similar devices.
+ *
+ * - E822 based devices have additional support for fine grained Vernier
+ * calibration which requires significant setup
+ * - The layout of timestamp data in the PHY register blocks is different
+ * - The way timer synchronization commands are issued is different.
+ *
+ * To support this, very low level functions have an e810 or e822 suffix
+ * indicating what type of device they work on. Higher level abstractions for
+ * tasks that can be done on both devices do not have the suffix and will
+ * correctly look up the appropriate low level function when running.
+ *
+ * Functions which only make sense on a single device family may not have
+ * a suitable generic implementation
+ */
+
+/**
+ * ice_get_ptp_src_clock_index - determine source clock index
+ * @hw: pointer to HW struct
+ *
+ * Determine the source clock index currently in use, based on device
+ * capabilities reported during initialization.
+ */
+u8 ice_get_ptp_src_clock_index(struct ice_hw *hw)
+{
+ return hw->func_caps.ts_func_info.tmr_index_assoc;
+}
+
+/**
+ * ice_ptp_read_src_incval - Read source timer increment value
+ * @hw: pointer to HW struct
+ *
+ * Read the increment value of the source timer and return it.
+ */
+static u64 ice_ptp_read_src_incval(struct ice_hw *hw)
+{
+ u32 lo, hi;
+ u8 tmr_idx;
+
+ tmr_idx = ice_get_ptp_src_clock_index(hw);
+
+ lo = rd32(hw, GLTSYN_INCVAL_L(tmr_idx));
+ hi = rd32(hw, GLTSYN_INCVAL_H(tmr_idx));
+
+ return ((u64)(hi & INCVAL_HIGH_M) << 32) | lo;
+}
+
+/**
+ * ice_ptp_src_cmd - Prepare source timer for a timer command
+ * @hw: pointer to HW structure
+ * @cmd: Timer command
+ *
+ * Prepare the source timer for an upcoming timer sync command.
+ */
+static void ice_ptp_src_cmd(struct ice_hw *hw, enum ice_ptp_tmr_cmd cmd)
+{
+ u32 cmd_val;
+ u8 tmr_idx;
+
+ tmr_idx = ice_get_ptp_src_clock_index(hw);
+ cmd_val = tmr_idx << SEL_CPK_SRC;
+
+ switch (cmd) {
+ case INIT_TIME:
+ cmd_val |= GLTSYN_CMD_INIT_TIME;
+ break;
+ case INIT_INCVAL:
+ cmd_val |= GLTSYN_CMD_INIT_INCVAL;
+ break;
+ case ADJ_TIME:
+ cmd_val |= GLTSYN_CMD_ADJ_TIME;
+ break;
+ case ADJ_TIME_AT_TIME:
+ cmd_val |= GLTSYN_CMD_ADJ_INIT_TIME;
+ break;
+ case READ_TIME:
+ cmd_val |= GLTSYN_CMD_READ_TIME;
+ break;
+ }
+
+ wr32(hw, GLTSYN_CMD, cmd_val);
+}
+
+/**
+ * ice_ptp_exec_tmr_cmd - Execute all prepared timer commands
+ * @hw: pointer to HW struct
+ *
+ * Write the SYNC_EXEC_CMD bit to the GLTSYN_CMD_SYNC register, and flush the
+ * write immediately. This triggers the hardware to begin executing all of the
+ * source and PHY timer commands synchronously.
+ */
+static void ice_ptp_exec_tmr_cmd(struct ice_hw *hw)
+{
+ wr32(hw, GLTSYN_CMD_SYNC, SYNC_EXEC_CMD);
+ ice_flush(hw);
+}
+
+/* E822 family functions
+ *
+ * The following functions operate on the E822 family of devices.
+ */
+
+/**
+ * ice_fill_phy_msg_e822 - Fill message data for a PHY register access
+ * @msg: the PHY message buffer to fill in
+ * @port: the port to access
+ * @offset: the register offset
+ */
+static void
+ice_fill_phy_msg_e822(struct ice_sbq_msg_input *msg, u8 port, u16 offset)
+{
+ int phy_port, phy, quadtype;
+
+ phy_port = port % ICE_PORTS_PER_PHY;
+ phy = port / ICE_PORTS_PER_PHY;
+ quadtype = (port / ICE_PORTS_PER_QUAD) % ICE_NUM_QUAD_TYPE;
+
+ if (quadtype == 0) {
+ msg->msg_addr_low = P_Q0_L(P_0_BASE + offset, phy_port);
+ msg->msg_addr_high = P_Q0_H(P_0_BASE + offset, phy_port);
+ } else {
+ msg->msg_addr_low = P_Q1_L(P_4_BASE + offset, phy_port);
+ msg->msg_addr_high = P_Q1_H(P_4_BASE + offset, phy_port);
+ }
+
+ if (phy == 0)
+ msg->dest_dev = rmn_0;
+ else if (phy == 1)
+ msg->dest_dev = rmn_1;
+ else
+ msg->dest_dev = rmn_2;
+}
+
+/**
+ * ice_is_64b_phy_reg_e822 - Check if this is a 64bit PHY register
+ * @low_addr: the low address to check
+ * @high_addr: on return, contains the high address of the 64bit register
+ *
+ * Checks if the provided low address is one of the known 64bit PHY values
+ * represented as two 32bit registers. If it is, return the appropriate high
+ * register offset to use.
+ */
+static bool ice_is_64b_phy_reg_e822(u16 low_addr, u16 *high_addr)
+{
+ switch (low_addr) {
+ case P_REG_PAR_PCS_TX_OFFSET_L:
+ *high_addr = P_REG_PAR_PCS_TX_OFFSET_U;
+ return true;
+ case P_REG_PAR_PCS_RX_OFFSET_L:
+ *high_addr = P_REG_PAR_PCS_RX_OFFSET_U;
+ return true;
+ case P_REG_PAR_TX_TIME_L:
+ *high_addr = P_REG_PAR_TX_TIME_U;
+ return true;
+ case P_REG_PAR_RX_TIME_L:
+ *high_addr = P_REG_PAR_RX_TIME_U;
+ return true;
+ case P_REG_TOTAL_TX_OFFSET_L:
+ *high_addr = P_REG_TOTAL_TX_OFFSET_U;
+ return true;
+ case P_REG_TOTAL_RX_OFFSET_L:
+ *high_addr = P_REG_TOTAL_RX_OFFSET_U;
+ return true;
+ case P_REG_UIX66_10G_40G_L:
+ *high_addr = P_REG_UIX66_10G_40G_U;
+ return true;
+ case P_REG_UIX66_25G_100G_L:
+ *high_addr = P_REG_UIX66_25G_100G_U;
+ return true;
+ case P_REG_TX_CAPTURE_L:
+ *high_addr = P_REG_TX_CAPTURE_U;
+ return true;
+ case P_REG_RX_CAPTURE_L:
+ *high_addr = P_REG_RX_CAPTURE_U;
+ return true;
+ case P_REG_TX_TIMER_INC_PRE_L:
+ *high_addr = P_REG_TX_TIMER_INC_PRE_U;
+ return true;
+ case P_REG_RX_TIMER_INC_PRE_L:
+ *high_addr = P_REG_RX_TIMER_INC_PRE_U;
+ return true;
+ default:
+ return false;
+ }
+}
+
+/**
+ * ice_is_40b_phy_reg_e822 - Check if this is a 40bit PHY register
+ * @low_addr: the low address to check
+ * @high_addr: on return, contains the high address of the 40bit value
+ *
+ * Checks if the provided low address is one of the known 40bit PHY values
+ * split into two registers with the lower 8 bits in the low register and the
+ * upper 32 bits in the high register. If it is, return the appropriate high
+ * register offset to use.
+ */
+static bool ice_is_40b_phy_reg_e822(u16 low_addr, u16 *high_addr)
+{
+ switch (low_addr) {
+ case P_REG_TIMETUS_L:
+ *high_addr = P_REG_TIMETUS_U;
+ return true;
+ case P_REG_PAR_RX_TUS_L:
+ *high_addr = P_REG_PAR_RX_TUS_U;
+ return true;
+ case P_REG_PAR_TX_TUS_L:
+ *high_addr = P_REG_PAR_TX_TUS_U;
+ return true;
+ case P_REG_PCS_RX_TUS_L:
+ *high_addr = P_REG_PCS_RX_TUS_U;
+ return true;
+ case P_REG_PCS_TX_TUS_L:
+ *high_addr = P_REG_PCS_TX_TUS_U;
+ return true;
+ case P_REG_DESK_PAR_RX_TUS_L:
+ *high_addr = P_REG_DESK_PAR_RX_TUS_U;
+ return true;
+ case P_REG_DESK_PAR_TX_TUS_L:
+ *high_addr = P_REG_DESK_PAR_TX_TUS_U;
+ return true;
+ case P_REG_DESK_PCS_RX_TUS_L:
+ *high_addr = P_REG_DESK_PCS_RX_TUS_U;
+ return true;
+ case P_REG_DESK_PCS_TX_TUS_L:
+ *high_addr = P_REG_DESK_PCS_TX_TUS_U;
+ return true;
+ default:
+ return false;
+ }
+}
+
+/**
+ * ice_read_phy_reg_e822 - Read a PHY register
+ * @hw: pointer to the HW struct
+ * @port: PHY port to read from
+ * @offset: PHY register offset to read
+ * @val: on return, the contents read from the PHY
+ *
+ * Read a PHY register for the given port over the device sideband queue.
+ */
+int
+ice_read_phy_reg_e822(struct ice_hw *hw, u8 port, u16 offset, u32 *val)
+{
+ struct ice_sbq_msg_input msg = {0};
+ int err;
+
+ ice_fill_phy_msg_e822(&msg, port, offset);
+ msg.opcode = ice_sbq_msg_rd;
+
+ err = ice_sbq_rw_reg(hw, &msg);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to send message to PHY, err %d\n",
+ err);
+ return err;
+ }
+
+ *val = msg.data;
+
+ return 0;
+}
+
+/**
+ * ice_read_64b_phy_reg_e822 - Read a 64bit value from PHY registers
+ * @hw: pointer to the HW struct
+ * @port: PHY port to read from
+ * @low_addr: offset of the lower register to read from
+ * @val: on return, the contents of the 64bit value from the PHY registers
+ *
+ * Reads the two registers associated with a 64bit value and returns it in the
+ * val pointer. The offset always specifies the lower register offset to use.
+ * The high offset is looked up. This function only operates on registers
+ * known to be two parts of a 64bit value.
+ */
+static int
+ice_read_64b_phy_reg_e822(struct ice_hw *hw, u8 port, u16 low_addr, u64 *val)
+{
+ u32 low, high;
+ u16 high_addr;
+ int err;
+
+ /* Only operate on registers known to be split into two 32bit
+ * registers.
+ */
+ if (!ice_is_64b_phy_reg_e822(low_addr, &high_addr)) {
+ ice_debug(hw, ICE_DBG_PTP, "Invalid 64b register addr 0x%08x\n",
+ low_addr);
+ return -EINVAL;
+ }
+
+ err = ice_read_phy_reg_e822(hw, port, low_addr, &low);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read from low register 0x%08x\n, err %d",
+ low_addr, err);
+ return err;
+ }
+
+ err = ice_read_phy_reg_e822(hw, port, high_addr, &high);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read from high register 0x%08x\n, err %d",
+ high_addr, err);
+ return err;
+ }
+
+ *val = (u64)high << 32 | low;
+
+ return 0;
+}
+
+/**
+ * ice_write_phy_reg_e822 - Write a PHY register
+ * @hw: pointer to the HW struct
+ * @port: PHY port to write to
+ * @offset: PHY register offset to write
+ * @val: The value to write to the register
+ *
+ * Write a PHY register for the given port over the device sideband queue.
+ */
+int
+ice_write_phy_reg_e822(struct ice_hw *hw, u8 port, u16 offset, u32 val)
+{
+ struct ice_sbq_msg_input msg = {0};
+ int err;
+
+ ice_fill_phy_msg_e822(&msg, port, offset);
+ msg.opcode = ice_sbq_msg_wr;
+ msg.data = val;
+
+ err = ice_sbq_rw_reg(hw, &msg);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to send message to PHY, err %d\n",
+ err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_write_40b_phy_reg_e822 - Write a 40b value to the PHY
+ * @hw: pointer to the HW struct
+ * @port: port to write to
+ * @low_addr: offset of the low register
+ * @val: 40b value to write
+ *
+ * Write the provided 40b value to the two associated registers by splitting
+ * it up into two chunks, the lower 8 bits and the upper 32 bits.
+ */
+static int
+ice_write_40b_phy_reg_e822(struct ice_hw *hw, u8 port, u16 low_addr, u64 val)
+{
+ u32 low, high;
+ u16 high_addr;
+ int err;
+
+ /* Only operate on registers known to be split into a lower 8 bit
+ * register and an upper 32 bit register.
+ */
+ if (!ice_is_40b_phy_reg_e822(low_addr, &high_addr)) {
+ ice_debug(hw, ICE_DBG_PTP, "Invalid 40b register addr 0x%08x\n",
+ low_addr);
+ return -EINVAL;
+ }
+
+ low = (u32)(val & P_REG_40B_LOW_M);
+ high = (u32)(val >> P_REG_40B_HIGH_S);
+
+ err = ice_write_phy_reg_e822(hw, port, low_addr, low);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write to low register 0x%08x\n, err %d",
+ low_addr, err);
+ return err;
+ }
+
+ err = ice_write_phy_reg_e822(hw, port, high_addr, high);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write to high register 0x%08x\n, err %d",
+ high_addr, err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_write_64b_phy_reg_e822 - Write a 64bit value to PHY registers
+ * @hw: pointer to the HW struct
+ * @port: PHY port to read from
+ * @low_addr: offset of the lower register to read from
+ * @val: the contents of the 64bit value to write to PHY
+ *
+ * Write the 64bit value to the two associated 32bit PHY registers. The offset
+ * is always specified as the lower register, and the high address is looked
+ * up. This function only operates on registers known to be two parts of
+ * a 64bit value.
+ */
+static int
+ice_write_64b_phy_reg_e822(struct ice_hw *hw, u8 port, u16 low_addr, u64 val)
+{
+ u32 low, high;
+ u16 high_addr;
+ int err;
+
+ /* Only operate on registers known to be split into two 32bit
+ * registers.
+ */
+ if (!ice_is_64b_phy_reg_e822(low_addr, &high_addr)) {
+ ice_debug(hw, ICE_DBG_PTP, "Invalid 64b register addr 0x%08x\n",
+ low_addr);
+ return -EINVAL;
+ }
+
+ low = lower_32_bits(val);
+ high = upper_32_bits(val);
+
+ err = ice_write_phy_reg_e822(hw, port, low_addr, low);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write to low register 0x%08x\n, err %d",
+ low_addr, err);
+ return err;
+ }
+
+ err = ice_write_phy_reg_e822(hw, port, high_addr, high);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write to high register 0x%08x\n, err %d",
+ high_addr, err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_fill_quad_msg_e822 - Fill message data for quad register access
+ * @msg: the PHY message buffer to fill in
+ * @quad: the quad to access
+ * @offset: the register offset
+ *
+ * Fill a message buffer for accessing a register in a quad shared between
+ * multiple PHYs.
+ */
+static void
+ice_fill_quad_msg_e822(struct ice_sbq_msg_input *msg, u8 quad, u16 offset)
+{
+ u32 addr;
+
+ msg->dest_dev = rmn_0;
+
+ if ((quad % ICE_NUM_QUAD_TYPE) == 0)
+ addr = Q_0_BASE + offset;
+ else
+ addr = Q_1_BASE + offset;
+
+ msg->msg_addr_low = lower_16_bits(addr);
+ msg->msg_addr_high = upper_16_bits(addr);
+}
+
+/**
+ * ice_read_quad_reg_e822 - Read a PHY quad register
+ * @hw: pointer to the HW struct
+ * @quad: quad to read from
+ * @offset: quad register offset to read
+ * @val: on return, the contents read from the quad
+ *
+ * Read a quad register over the device sideband queue. Quad registers are
+ * shared between multiple PHYs.
+ */
+int
+ice_read_quad_reg_e822(struct ice_hw *hw, u8 quad, u16 offset, u32 *val)
+{
+ struct ice_sbq_msg_input msg = {0};
+ int err;
+
+ if (quad >= ICE_MAX_QUAD)
+ return -EINVAL;
+
+ ice_fill_quad_msg_e822(&msg, quad, offset);
+ msg.opcode = ice_sbq_msg_rd;
+
+ err = ice_sbq_rw_reg(hw, &msg);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to send message to PHY, err %d\n",
+ err);
+ return err;
+ }
+
+ *val = msg.data;
+
+ return 0;
+}
+
+/**
+ * ice_write_quad_reg_e822 - Write a PHY quad register
+ * @hw: pointer to the HW struct
+ * @quad: quad to write to
+ * @offset: quad register offset to write
+ * @val: The value to write to the register
+ *
+ * Write a quad register over the device sideband queue. Quad registers are
+ * shared between multiple PHYs.
+ */
+int
+ice_write_quad_reg_e822(struct ice_hw *hw, u8 quad, u16 offset, u32 val)
+{
+ struct ice_sbq_msg_input msg = {0};
+ int err;
+
+ if (quad >= ICE_MAX_QUAD)
+ return -EINVAL;
+
+ ice_fill_quad_msg_e822(&msg, quad, offset);
+ msg.opcode = ice_sbq_msg_wr;
+ msg.data = val;
+
+ err = ice_sbq_rw_reg(hw, &msg);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to send message to PHY, err %d\n",
+ err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_read_phy_tstamp_e822 - Read a PHY timestamp out of the quad block
+ * @hw: pointer to the HW struct
+ * @quad: the quad to read from
+ * @idx: the timestamp index to read
+ * @tstamp: on return, the 40bit timestamp value
+ *
+ * Read a 40bit timestamp value out of the two associated registers in the
+ * quad memory block that is shared between the internal PHYs of the E822
+ * family of devices.
+ */
+static int
+ice_read_phy_tstamp_e822(struct ice_hw *hw, u8 quad, u8 idx, u64 *tstamp)
+{
+ u16 lo_addr, hi_addr;
+ u32 lo, hi;
+ int err;
+
+ lo_addr = (u16)TS_L(Q_REG_TX_MEMORY_BANK_START, idx);
+ hi_addr = (u16)TS_H(Q_REG_TX_MEMORY_BANK_START, idx);
+
+ err = ice_read_quad_reg_e822(hw, quad, lo_addr, &lo);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read low PTP timestamp register, err %d\n",
+ err);
+ return err;
+ }
+
+ err = ice_read_quad_reg_e822(hw, quad, hi_addr, &hi);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read high PTP timestamp register, err %d\n",
+ err);
+ return err;
+ }
+
+ /* For E822 based internal PHYs, the timestamp is reported with the
+ * lower 8 bits in the low register, and the upper 32 bits in the high
+ * register.
+ */
+ *tstamp = ((u64)hi) << TS_PHY_HIGH_S | ((u64)lo & TS_PHY_LOW_M);
+
+ return 0;
+}
+
+/**
+ * ice_clear_phy_tstamp_e822 - Clear a timestamp from the quad block
+ * @hw: pointer to the HW struct
+ * @quad: the quad to read from
+ * @idx: the timestamp index to reset
+ *
+ * Clear a timestamp, resetting its valid bit, from the PHY quad block that is
+ * shared between the internal PHYs on the E822 devices.
+ */
+static int
+ice_clear_phy_tstamp_e822(struct ice_hw *hw, u8 quad, u8 idx)
+{
+ u16 lo_addr, hi_addr;
+ int err;
+
+ lo_addr = (u16)TS_L(Q_REG_TX_MEMORY_BANK_START, idx);
+ hi_addr = (u16)TS_H(Q_REG_TX_MEMORY_BANK_START, idx);
+
+ err = ice_write_quad_reg_e822(hw, quad, lo_addr, 0);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to clear low PTP timestamp register, err %d\n",
+ err);
+ return err;
+ }
+
+ err = ice_write_quad_reg_e822(hw, quad, hi_addr, 0);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to clear high PTP timestamp register, err %d\n",
+ err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_ptp_set_vernier_wl - Set the window length for vernier calibration
+ * @hw: pointer to the HW struct
+ *
+ * Set the window length used for the vernier port calibration process.
+ */
+static int ice_ptp_set_vernier_wl(struct ice_hw *hw)
+{
+ u8 port;
+
+ for (port = 0; port < ICE_NUM_EXTERNAL_PORTS; port++) {
+ int err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_WL,
+ PTP_VERNIER_WL);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to set vernier window length for port %u, err %d\n",
+ port, err);
+ return err;
+ }
+ }
+
+ return 0;
+}
+
+/**
+ * ice_ptp_init_phc_e822 - Perform E822 specific PHC initialization
+ * @hw: pointer to HW struct
+ *
+ * Perform PHC initialization steps specific to E822 devices.
+ */
+static int ice_ptp_init_phc_e822(struct ice_hw *hw)
+{
+ u32 regval;
+
+ /* Enable reading switch and PHY registers over the sideband queue */
+#define PF_SB_REM_DEV_CTL_SWITCH_READ BIT(1)
+#define PF_SB_REM_DEV_CTL_PHY0 BIT(2)
+ regval = rd32(hw, PF_SB_REM_DEV_CTL);
+ regval |= (PF_SB_REM_DEV_CTL_SWITCH_READ |
+ PF_SB_REM_DEV_CTL_PHY0);
+ wr32(hw, PF_SB_REM_DEV_CTL, regval);
+
+ /* Set window length for all the ports */
+ return ice_ptp_set_vernier_wl(hw);
+}
+
+/**
+ * ice_ptp_prep_phy_time_e822 - Prepare PHY port with initial time
+ * @hw: pointer to the HW struct
+ * @time: Time to initialize the PHY port clocks to
+ *
+ * Program the PHY port registers with a new initial time value. The port
+ * clock will be initialized once the driver issues an INIT_TIME sync
+ * command. The time value is the upper 32 bits of the PHY timer, usually in
+ * units of nominal nanoseconds.
+ */
+static int
+ice_ptp_prep_phy_time_e822(struct ice_hw *hw, u32 time)
+{
+ u64 phy_time;
+ u8 port;
+ int err;
+
+ /* The time represents the upper 32 bits of the PHY timer, so we need
+ * to shift to account for this when programming.
+ */
+ phy_time = (u64)time << 32;
+
+ for (port = 0; port < ICE_NUM_EXTERNAL_PORTS; port++) {
+ /* Tx case */
+ err = ice_write_64b_phy_reg_e822(hw, port,
+ P_REG_TX_TIMER_INC_PRE_L,
+ phy_time);
+ if (err)
+ goto exit_err;
+
+ /* Rx case */
+ err = ice_write_64b_phy_reg_e822(hw, port,
+ P_REG_RX_TIMER_INC_PRE_L,
+ phy_time);
+ if (err)
+ goto exit_err;
+ }
+
+ return 0;
+
+exit_err:
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write init time for port %u, err %d\n",
+ port, err);
+
+ return err;
+}
+
+/**
+ * ice_ptp_prep_port_adj_e822 - Prepare a single port for time adjust
+ * @hw: pointer to HW struct
+ * @port: Port number to be programmed
+ * @time: time in cycles to adjust the port Tx and Rx clocks
+ *
+ * Program the port for an atomic adjustment by writing the Tx and Rx timer
+ * registers. The atomic adjustment won't be completed until the driver issues
+ * an ADJ_TIME command.
+ *
+ * Note that time is not in units of nanoseconds. It is in clock time
+ * including the lower sub-nanosecond portion of the port timer.
+ *
+ * Negative adjustments are supported using 2s complement arithmetic.
+ */
+int
+ice_ptp_prep_port_adj_e822(struct ice_hw *hw, u8 port, s64 time)
+{
+ u32 l_time, u_time;
+ int err;
+
+ l_time = lower_32_bits(time);
+ u_time = upper_32_bits(time);
+
+ /* Tx case */
+ err = ice_write_phy_reg_e822(hw, port, P_REG_TX_TIMER_INC_PRE_L,
+ l_time);
+ if (err)
+ goto exit_err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_TX_TIMER_INC_PRE_U,
+ u_time);
+ if (err)
+ goto exit_err;
+
+ /* Rx case */
+ err = ice_write_phy_reg_e822(hw, port, P_REG_RX_TIMER_INC_PRE_L,
+ l_time);
+ if (err)
+ goto exit_err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_RX_TIMER_INC_PRE_U,
+ u_time);
+ if (err)
+ goto exit_err;
+
+ return 0;
+
+exit_err:
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write time adjust for port %u, err %d\n",
+ port, err);
+ return err;
+}
+
+/**
+ * ice_ptp_prep_phy_adj_e822 - Prep PHY ports for a time adjustment
+ * @hw: pointer to HW struct
+ * @adj: adjustment in nanoseconds
+ *
+ * Prepare the PHY ports for an atomic time adjustment by programming the PHY
+ * Tx and Rx port registers. The actual adjustment is completed by issuing an
+ * ADJ_TIME or ADJ_TIME_AT_TIME sync command.
+ */
+static int
+ice_ptp_prep_phy_adj_e822(struct ice_hw *hw, s32 adj)
+{
+ s64 cycles;
+ u8 port;
+
+ /* The port clock supports adjustment of the sub-nanosecond portion of
+ * the clock. We shift the provided adjustment in nanoseconds to
+ * calculate the appropriate adjustment to program into the PHY ports.
+ */
+ if (adj > 0)
+ cycles = (s64)adj << 32;
+ else
+ cycles = -(((s64)-adj) << 32);
+
+ for (port = 0; port < ICE_NUM_EXTERNAL_PORTS; port++) {
+ int err;
+
+ err = ice_ptp_prep_port_adj_e822(hw, port, cycles);
+ if (err)
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_ptp_prep_phy_incval_e822 - Prepare PHY ports for time adjustment
+ * @hw: pointer to HW struct
+ * @incval: new increment value to prepare
+ *
+ * Prepare each of the PHY ports for a new increment value by programming the
+ * port's TIMETUS registers. The new increment value will be updated after
+ * issuing an INIT_INCVAL command.
+ */
+static int
+ice_ptp_prep_phy_incval_e822(struct ice_hw *hw, u64 incval)
+{
+ int err;
+ u8 port;
+
+ for (port = 0; port < ICE_NUM_EXTERNAL_PORTS; port++) {
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_TIMETUS_L,
+ incval);
+ if (err)
+ goto exit_err;
+ }
+
+ return 0;
+
+exit_err:
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write incval for port %u, err %d\n",
+ port, err);
+
+ return err;
+}
+
+/**
+ * ice_ptp_read_port_capture - Read a port's local time capture
+ * @hw: pointer to HW struct
+ * @port: Port number to read
+ * @tx_ts: on return, the Tx port time capture
+ * @rx_ts: on return, the Rx port time capture
+ *
+ * Read the port's Tx and Rx local time capture values.
+ *
+ * Note this has no equivalent for the E810 devices.
+ */
+static int
+ice_ptp_read_port_capture(struct ice_hw *hw, u8 port, u64 *tx_ts, u64 *rx_ts)
+{
+ int err;
+
+ /* Tx case */
+ err = ice_read_64b_phy_reg_e822(hw, port, P_REG_TX_CAPTURE_L, tx_ts);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read REG_TX_CAPTURE, err %d\n",
+ err);
+ return err;
+ }
+
+ ice_debug(hw, ICE_DBG_PTP, "tx_init = 0x%016llx\n",
+ (unsigned long long)*tx_ts);
+
+ /* Rx case */
+ err = ice_read_64b_phy_reg_e822(hw, port, P_REG_RX_CAPTURE_L, rx_ts);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read RX_CAPTURE, err %d\n",
+ err);
+ return err;
+ }
+
+ ice_debug(hw, ICE_DBG_PTP, "rx_init = 0x%016llx\n",
+ (unsigned long long)*rx_ts);
+
+ return 0;
+}
+
+/**
+ * ice_ptp_one_port_cmd - Prepare a single PHY port for a timer command
+ * @hw: pointer to HW struct
+ * @port: Port to which cmd has to be sent
+ * @cmd: Command to be sent to the port
+ *
+ * Prepare the requested port for an upcoming timer sync command.
+ *
+ * Note there is no equivalent of this operation on E810, as that device
+ * always handles all external PHYs internally.
+ */
+static int
+ice_ptp_one_port_cmd(struct ice_hw *hw, u8 port, enum ice_ptp_tmr_cmd cmd)
+{
+ u32 cmd_val, val;
+ u8 tmr_idx;
+ int err;
+
+ tmr_idx = ice_get_ptp_src_clock_index(hw);
+ cmd_val = tmr_idx << SEL_PHY_SRC;
+ switch (cmd) {
+ case INIT_TIME:
+ cmd_val |= PHY_CMD_INIT_TIME;
+ break;
+ case INIT_INCVAL:
+ cmd_val |= PHY_CMD_INIT_INCVAL;
+ break;
+ case ADJ_TIME:
+ cmd_val |= PHY_CMD_ADJ_TIME;
+ break;
+ case READ_TIME:
+ cmd_val |= PHY_CMD_READ_TIME;
+ break;
+ case ADJ_TIME_AT_TIME:
+ cmd_val |= PHY_CMD_ADJ_TIME_AT_TIME;
+ break;
+ }
+
+ /* Tx case */
+ /* Read, modify, write */
+ err = ice_read_phy_reg_e822(hw, port, P_REG_TX_TMR_CMD, &val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read TX_TMR_CMD, err %d\n",
+ err);
+ return err;
+ }
+
+ /* Modify necessary bits only and perform write */
+ val &= ~TS_CMD_MASK;
+ val |= cmd_val;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_TX_TMR_CMD, val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write back TX_TMR_CMD, err %d\n",
+ err);
+ return err;
+ }
+
+ /* Rx case */
+ /* Read, modify, write */
+ err = ice_read_phy_reg_e822(hw, port, P_REG_RX_TMR_CMD, &val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read RX_TMR_CMD, err %d\n",
+ err);
+ return err;
+ }
+
+ /* Modify necessary bits only and perform write */
+ val &= ~TS_CMD_MASK;
+ val |= cmd_val;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_RX_TMR_CMD, val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write back RX_TMR_CMD, err %d\n",
+ err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_ptp_port_cmd_e822 - Prepare all ports for a timer command
+ * @hw: pointer to the HW struct
+ * @cmd: timer command to prepare
+ *
+ * Prepare all ports connected to this device for an upcoming timer sync
+ * command.
+ */
+static int
+ice_ptp_port_cmd_e822(struct ice_hw *hw, enum ice_ptp_tmr_cmd cmd)
+{
+ u8 port;
+
+ for (port = 0; port < ICE_NUM_EXTERNAL_PORTS; port++) {
+ int err;
+
+ err = ice_ptp_one_port_cmd(hw, port, cmd);
+ if (err)
+ return err;
+ }
+
+ return 0;
+}
+
+/* E822 Vernier calibration functions
+ *
+ * The following functions are used as part of the vernier calibration of
+ * a port. This calibration increases the precision of the timestamps on the
+ * port.
+ */
+
+/**
+ * ice_phy_get_speed_and_fec_e822 - Get link speed and FEC based on serdes mode
+ * @hw: pointer to HW struct
+ * @port: the port to read from
+ * @link_out: if non-NULL, holds link speed on success
+ * @fec_out: if non-NULL, holds FEC algorithm on success
+ *
+ * Read the serdes data for the PHY port and extract the link speed and FEC
+ * algorithm.
+ */
+static int
+ice_phy_get_speed_and_fec_e822(struct ice_hw *hw, u8 port,
+ enum ice_ptp_link_spd *link_out,
+ enum ice_ptp_fec_mode *fec_out)
+{
+ enum ice_ptp_link_spd link;
+ enum ice_ptp_fec_mode fec;
+ u32 serdes;
+ int err;
+
+ err = ice_read_phy_reg_e822(hw, port, P_REG_LINK_SPEED, &serdes);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read serdes info\n");
+ return err;
+ }
+
+ /* Determine the FEC algorithm */
+ fec = (enum ice_ptp_fec_mode)P_REG_LINK_SPEED_FEC_MODE(serdes);
+
+ serdes &= P_REG_LINK_SPEED_SERDES_M;
+
+ /* Determine the link speed */
+ if (fec == ICE_PTP_FEC_MODE_RS_FEC) {
+ switch (serdes) {
+ case ICE_PTP_SERDES_25G:
+ link = ICE_PTP_LNK_SPD_25G_RS;
+ break;
+ case ICE_PTP_SERDES_50G:
+ link = ICE_PTP_LNK_SPD_50G_RS;
+ break;
+ case ICE_PTP_SERDES_100G:
+ link = ICE_PTP_LNK_SPD_100G_RS;
+ break;
+ default:
+ return -EIO;
+ }
+ } else {
+ switch (serdes) {
+ case ICE_PTP_SERDES_1G:
+ link = ICE_PTP_LNK_SPD_1G;
+ break;
+ case ICE_PTP_SERDES_10G:
+ link = ICE_PTP_LNK_SPD_10G;
+ break;
+ case ICE_PTP_SERDES_25G:
+ link = ICE_PTP_LNK_SPD_25G;
+ break;
+ case ICE_PTP_SERDES_40G:
+ link = ICE_PTP_LNK_SPD_40G;
+ break;
+ case ICE_PTP_SERDES_50G:
+ link = ICE_PTP_LNK_SPD_50G;
+ break;
+ default:
+ return -EIO;
+ }
+ }
+
+ if (link_out)
+ *link_out = link;
+ if (fec_out)
+ *fec_out = fec;
+
+ return 0;
+}
+
+/**
+ * ice_phy_cfg_lane_e822 - Configure PHY quad for single/multi-lane timestamp
+ * @hw: pointer to HW struct
+ * @port: to configure the quad for
+ */
+static void ice_phy_cfg_lane_e822(struct ice_hw *hw, u8 port)
+{
+ enum ice_ptp_link_spd link_spd;
+ int err;
+ u32 val;
+ u8 quad;
+
+ err = ice_phy_get_speed_and_fec_e822(hw, port, &link_spd, NULL);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to get PHY link speed, err %d\n",
+ err);
+ return;
+ }
+
+ quad = port / ICE_PORTS_PER_QUAD;
+
+ err = ice_read_quad_reg_e822(hw, quad, Q_REG_TX_MEM_GBL_CFG, &val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to read TX_MEM_GLB_CFG, err %d\n",
+ err);
+ return;
+ }
+
+ if (link_spd >= ICE_PTP_LNK_SPD_40G)
+ val &= ~Q_REG_TX_MEM_GBL_CFG_LANE_TYPE_M;
+ else
+ val |= Q_REG_TX_MEM_GBL_CFG_LANE_TYPE_M;
+
+ err = ice_write_quad_reg_e822(hw, quad, Q_REG_TX_MEM_GBL_CFG, val);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write back TX_MEM_GBL_CFG, err %d\n",
+ err);
+ return;
+ }
+}
+
+/**
+ * ice_phy_cfg_uix_e822 - Configure Serdes UI to TU conversion for E822
+ * @hw: pointer to the HW structure
+ * @port: the port to configure
+ *
+ * Program the conversion ration of Serdes clock "unit intervals" (UIs) to PHC
+ * hardware clock time units (TUs). That is, determine the number of TUs per
+ * serdes unit interval, and program the UIX registers with this conversion.
+ *
+ * This conversion is used as part of the calibration process when determining
+ * the additional error of a timestamp vs the real time of transmission or
+ * receipt of the packet.
+ *
+ * Hardware uses the number of TUs per 66 UIs, written to the UIX registers
+ * for the two main serdes clock rates, 10G/40G and 25G/100G serdes clocks.
+ *
+ * To calculate the conversion ratio, we use the following facts:
+ *
+ * a) the clock frequency in Hz (cycles per second)
+ * b) the number of TUs per cycle (the increment value of the clock)
+ * c) 1 second per 1 billion nanoseconds
+ * d) the duration of 66 UIs in nanoseconds
+ *
+ * Given these facts, we can use the following table to work out what ratios
+ * to multiply in order to get the number of TUs per 66 UIs:
+ *
+ * cycles | 1 second | incval (TUs) | nanoseconds
+ * -------+--------------+--------------+-------------
+ * second | 1 billion ns | cycle | 66 UIs
+ *
+ * To perform the multiplication using integers without too much loss of
+ * precision, we can take use the following equation:
+ *
+ * (freq * incval * 6600 LINE_UI ) / ( 100 * 1 billion)
+ *
+ * We scale up to using 6600 UI instead of 66 in order to avoid fractional
+ * nanosecond UIs (66 UI at 10G/40G is 6.4 ns)
+ *
+ * The increment value has a maximum expected range of about 34 bits, while
+ * the frequency value is about 29 bits. Multiplying these values shouldn't
+ * overflow the 64 bits. However, we must then further multiply them again by
+ * the Serdes unit interval duration. To avoid overflow here, we split the
+ * overall divide by 1e11 into a divide by 256 (shift down by 8 bits) and
+ * a divide by 390,625,000. This does lose some precision, but avoids
+ * miscalculation due to arithmetic overflow.
+ */
+static int ice_phy_cfg_uix_e822(struct ice_hw *hw, u8 port)
+{
+ u64 cur_freq, clk_incval, tu_per_sec, uix;
+ int err;
+
+ cur_freq = ice_e822_pll_freq(ice_e822_time_ref(hw));
+ clk_incval = ice_ptp_read_src_incval(hw);
+
+ /* Calculate TUs per second divided by 256 */
+ tu_per_sec = (cur_freq * clk_incval) >> 8;
+
+#define LINE_UI_10G_40G 640 /* 6600 UIs is 640 nanoseconds at 10Gb/40Gb */
+#define LINE_UI_25G_100G 256 /* 6600 UIs is 256 nanoseconds at 25Gb/100Gb */
+
+ /* Program the 10Gb/40Gb conversion ratio */
+ uix = div_u64(tu_per_sec * LINE_UI_10G_40G, 390625000);
+
+ err = ice_write_64b_phy_reg_e822(hw, port, P_REG_UIX66_10G_40G_L,
+ uix);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write UIX66_10G_40G, err %d\n",
+ err);
+ return err;
+ }
+
+ /* Program the 25Gb/100Gb conversion ratio */
+ uix = div_u64(tu_per_sec * LINE_UI_25G_100G, 390625000);
+
+ err = ice_write_64b_phy_reg_e822(hw, port, P_REG_UIX66_25G_100G_L,
+ uix);
+ if (err) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to write UIX66_25G_100G, err %d\n",
+ err);
+ return err;
+ }
+
+ return 0;
+}
+
+/**
+ * ice_phy_cfg_parpcs_e822 - Configure TUs per PAR/PCS clock cycle
+ * @hw: pointer to the HW struct
+ * @port: port to configure
+ *
+ * Configure the number of TUs for the PAR and PCS clocks used as part of the
+ * timestamp calibration process. This depends on the link speed, as the PHY
+ * uses different markers depending on the speed.
+ *
+ * 1Gb/10Gb/25Gb:
+ * - Tx/Rx PAR/PCS markers
+ *
+ * 25Gb RS:
+ * - Tx/Rx Reed Solomon gearbox PAR/PCS markers
+ *
+ * 40Gb/50Gb:
+ * - Tx/Rx PAR/PCS markers
+ * - Rx Deskew PAR/PCS markers
+ *
+ * 50G RS and 100GB RS:
+ * - Tx/Rx Reed Solomon gearbox PAR/PCS markers
+ * - Rx Deskew PAR/PCS markers
+ * - Tx PAR/PCS markers
+ *
+ * To calculate the conversion, we use the PHC clock frequency (cycles per
+ * second), the increment value (TUs per cycle), and the related PHY clock
+ * frequency to calculate the TUs per unit of the PHY link clock. The
+ * following table shows how the units convert:
+ *
+ * cycles | TUs | second
+ * -------+-------+--------
+ * second | cycle | cycles
+ *
+ * For each conversion register, look up the appropriate frequency from the
+ * e822 PAR/PCS table and calculate the TUs per unit of that clock. Program
+ * this to the appropriate register, preparing hardware to perform timestamp
+ * calibration to calculate the total Tx or Rx offset to adjust the timestamp
+ * in order to calibrate for the internal PHY delays.
+ *
+ * Note that the increment value ranges up to ~34 bits, and the clock
+ * frequency is ~29 bits, so multiplying them together should fit within the
+ * 64 bit arithmetic.
+ */
+static int ice_phy_cfg_parpcs_e822(struct ice_hw *hw, u8 port)
+{
+ u64 cur_freq, clk_incval, tu_per_sec, phy_tus;
+ enum ice_ptp_link_spd link_spd;
+ enum ice_ptp_fec_mode fec_mode;
+ int err;
+
+ err = ice_phy_get_speed_and_fec_e822(hw, port, &link_spd, &fec_mode);
+ if (err)
+ return err;
+
+ cur_freq = ice_e822_pll_freq(ice_e822_time_ref(hw));
+ clk_incval = ice_ptp_read_src_incval(hw);
+
+ /* Calculate TUs per cycle of the PHC clock */
+ tu_per_sec = cur_freq * clk_incval;
+
+ /* For each PHY conversion register, look up the appropriate link
+ * speed frequency and determine the TUs per that clock's cycle time.
+ * Split this into a high and low value and then program the
+ * appropriate register. If that link speed does not use the
+ * associated register, write zeros to clear it instead.
+ */
+
+ /* P_REG_PAR_TX_TUS */
+ if (e822_vernier[link_spd].tx_par_clk)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].tx_par_clk);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_PAR_TX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_PAR_RX_TUS */
+ if (e822_vernier[link_spd].rx_par_clk)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].rx_par_clk);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_PAR_RX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_PCS_TX_TUS */
+ if (e822_vernier[link_spd].tx_pcs_clk)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].tx_pcs_clk);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_PCS_TX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_PCS_RX_TUS */
+ if (e822_vernier[link_spd].rx_pcs_clk)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].rx_pcs_clk);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_PCS_RX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_DESK_PAR_TX_TUS */
+ if (e822_vernier[link_spd].tx_desk_rsgb_par)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].tx_desk_rsgb_par);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_DESK_PAR_TX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_DESK_PAR_RX_TUS */
+ if (e822_vernier[link_spd].rx_desk_rsgb_par)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].rx_desk_rsgb_par);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_DESK_PAR_RX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_DESK_PCS_TX_TUS */
+ if (e822_vernier[link_spd].tx_desk_rsgb_pcs)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].tx_desk_rsgb_pcs);
+ else
+ phy_tus = 0;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_DESK_PCS_TX_TUS_L,
+ phy_tus);
+ if (err)
+ return err;
+
+ /* P_REG_DESK_PCS_RX_TUS */
+ if (e822_vernier[link_spd].rx_desk_rsgb_pcs)
+ phy_tus = div_u64(tu_per_sec,
+ e822_vernier[link_spd].rx_desk_rsgb_pcs);
+ else
+ phy_tus = 0;
+
+ return ice_write_40b_phy_reg_e822(hw, port, P_REG_DESK_PCS_RX_TUS_L,
+ phy_tus);
+}
+
+/**
+ * ice_calc_fixed_tx_offset_e822 - Calculated Fixed Tx offset for a port
+ * @hw: pointer to the HW struct
+ * @link_spd: the Link speed to calculate for
+ *
+ * Calculate the fixed offset due to known static latency data.
*/
+static u64
+ice_calc_fixed_tx_offset_e822(struct ice_hw *hw, enum ice_ptp_link_spd link_spd)
+{
+ u64 cur_freq, clk_incval, tu_per_sec, fixed_offset;
+
+ cur_freq = ice_e822_pll_freq(ice_e822_time_ref(hw));
+ clk_incval = ice_ptp_read_src_incval(hw);
+
+ /* Calculate TUs per second */
+ tu_per_sec = cur_freq * clk_incval;
+
+ /* Calculate number of TUs to add for the fixed Tx latency. Since the
+ * latency measurement is in 1/100th of a nanosecond, we need to
+ * multiply by tu_per_sec and then divide by 1e11. This calculation
+ * overflows 64 bit integer arithmetic, so break it up into two
+ * divisions by 1e4 first then by 1e7.
+ */
+ fixed_offset = div_u64(tu_per_sec, 10000);
+ fixed_offset *= e822_vernier[link_spd].tx_fixed_delay;
+ fixed_offset = div_u64(fixed_offset, 10000000);
+
+ return fixed_offset;
+}
/**
- * ice_get_ptp_src_clock_index - determine source clock index
+ * ice_phy_cfg_fixed_tx_offset_e822 - Configure Tx offset for bypass mode
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to configure
+ *
+ * Calculate and program the fixed Tx offset, and indicate that the offset is
+ * ready. This can be used when operating in bypass mode.
+ */
+static int
+ice_phy_cfg_fixed_tx_offset_e822(struct ice_hw *hw, u8 port)
+{
+ enum ice_ptp_link_spd link_spd;
+ enum ice_ptp_fec_mode fec_mode;
+ u64 total_offset;
+ int err;
+
+ err = ice_phy_get_speed_and_fec_e822(hw, port, &link_spd, &fec_mode);
+ if (err)
+ return err;
+
+ total_offset = ice_calc_fixed_tx_offset_e822(hw, link_spd);
+
+ /* Program the fixed Tx offset into the P_REG_TOTAL_TX_OFFSET_L
+ * register, then indicate that the Tx offset is ready. After this,
+ * timestamps will be enabled.
+ *
+ * Note that this skips including the more precise offsets generated
+ * by the Vernier calibration.
+ */
+ err = ice_write_64b_phy_reg_e822(hw, port, P_REG_TOTAL_TX_OFFSET_L,
+ total_offset);
+ if (err)
+ return err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_TX_OR, 1);
+ if (err)
+ return err;
+
+ return 0;
+}
+
+/**
+ * ice_calc_fixed_rx_offset_e822 - Calculated the fixed Rx offset for a port
* @hw: pointer to HW struct
+ * @link_spd: The Link speed to calculate for
*
- * Determine the source clock index currently in use, based on device
- * capabilities reported during initialization.
+ * Determine the fixed Rx latency for a given link speed.
*/
-u8 ice_get_ptp_src_clock_index(struct ice_hw *hw)
+static u64
+ice_calc_fixed_rx_offset_e822(struct ice_hw *hw, enum ice_ptp_link_spd link_spd)
{
- return hw->func_caps.ts_func_info.tmr_index_assoc;
+ u64 cur_freq, clk_incval, tu_per_sec, fixed_offset;
+
+ cur_freq = ice_e822_pll_freq(ice_e822_time_ref(hw));
+ clk_incval = ice_ptp_read_src_incval(hw);
+
+ /* Calculate TUs per second */
+ tu_per_sec = cur_freq * clk_incval;
+
+ /* Calculate number of TUs to add for the fixed Rx latency. Since the
+ * latency measurement is in 1/100th of a nanosecond, we need to
+ * multiply by tu_per_sec and then divide by 1e11. This calculation
+ * overflows 64 bit integer arithmetic, so break it up into two
+ * divisions by 1e4 first then by 1e7.
+ */
+ fixed_offset = div_u64(tu_per_sec, 10000);
+ fixed_offset *= e822_vernier[link_spd].rx_fixed_delay;
+ fixed_offset = div_u64(fixed_offset, 10000000);
+
+ return fixed_offset;
+}
+
+/**
+ * ice_phy_cfg_fixed_rx_offset_e822 - Configure fixed Rx offset for bypass mode
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to configure
+ *
+ * Calculate and program the fixed Rx offset, and indicate that the offset is
+ * ready. This can be used when operating in bypass mode.
+ */
+static int
+ice_phy_cfg_fixed_rx_offset_e822(struct ice_hw *hw, u8 port)
+{
+ enum ice_ptp_link_spd link_spd;
+ enum ice_ptp_fec_mode fec_mode;
+ u64 total_offset;
+ int err;
+
+ err = ice_phy_get_speed_and_fec_e822(hw, port, &link_spd, &fec_mode);
+ if (err)
+ return err;
+
+ total_offset = ice_calc_fixed_rx_offset_e822(hw, link_spd);
+
+ /* Program the fixed Rx offset into the P_REG_TOTAL_RX_OFFSET_L
+ * register, then indicate that the Rx offset is ready. After this,
+ * timestamps will be enabled.
+ *
+ * Note that this skips including the more precise offsets generated
+ * by Vernier calibration.
+ */
+ err = ice_write_64b_phy_reg_e822(hw, port, P_REG_TOTAL_RX_OFFSET_L,
+ total_offset);
+ if (err)
+ return err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_RX_OR, 1);
+ if (err)
+ return err;
+
+ return 0;
+}
+
+/**
+ * ice_read_phy_and_phc_time_e822 - Simultaneously capture PHC and PHY time
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to read
+ * @phy_time: on return, the 64bit PHY timer value
+ * @phc_time: on return, the lower 64bits of PHC time
+ *
+ * Issue a READ_TIME timer command to simultaneously capture the PHY and PHC
+ * timer values.
+ */
+static int
+ice_read_phy_and_phc_time_e822(struct ice_hw *hw, u8 port, u64 *phy_time,
+ u64 *phc_time)
+{
+ u64 tx_time, rx_time;
+ u32 zo, lo;
+ u8 tmr_idx;
+ int err;
+
+ tmr_idx = ice_get_ptp_src_clock_index(hw);
+
+ /* Prepare the PHC timer for a READ_TIME capture command */
+ ice_ptp_src_cmd(hw, READ_TIME);
+
+ /* Prepare the PHY timer for a READ_TIME capture command */
+ err = ice_ptp_one_port_cmd(hw, port, READ_TIME);
+ if (err)
+ return err;
+
+ /* Issue the sync to start the READ_TIME capture */
+ ice_ptp_exec_tmr_cmd(hw);
+
+ /* Read the captured PHC time from the shadow time registers */
+ zo = rd32(hw, GLTSYN_SHTIME_0(tmr_idx));
+ lo = rd32(hw, GLTSYN_SHTIME_L(tmr_idx));
+ *phc_time = (u64)lo << 32 | zo;
+
+ /* Read the captured PHY time from the PHY shadow registers */
+ err = ice_ptp_read_port_capture(hw, port, &tx_time, &rx_time);
+ if (err)
+ return err;
+
+ /* If the PHY Tx and Rx timers don't match, log a warning message.
+ * Note that this should not happen in normal circumstances since the
+ * driver always programs them together.
+ */
+ if (tx_time != rx_time)
+ dev_warn(ice_hw_to_dev(hw),
+ "PHY port %u Tx and Rx timers do not match, tx_time 0x%016llX, rx_time 0x%016llX\n",
+ port, (unsigned long long)tx_time,
+ (unsigned long long)rx_time);
+
+ *phy_time = tx_time;
+
+ return 0;
+}
+
+/**
+ * ice_sync_phy_timer_e822 - Synchronize the PHY timer with PHC timer
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to synchronize
+ *
+ * Perform an adjustment to ensure that the PHY and PHC timers are in sync.
+ * This is done by issuing a READ_TIME command which triggers a simultaneous
+ * read of the PHY timer and PHC timer. Then we use the difference to
+ * calculate an appropriate 2s complement addition to add to the PHY timer in
+ * order to ensure it reads the same value as the primary PHC timer.
+ */
+static int ice_sync_phy_timer_e822(struct ice_hw *hw, u8 port)
+{
+ u64 phc_time, phy_time, difference;
+ int err;
+
+ if (!ice_ptp_lock(hw)) {
+ ice_debug(hw, ICE_DBG_PTP, "Failed to acquire PTP semaphore\n");
+ return -EBUSY;
+ }
+
+ err = ice_read_phy_and_phc_time_e822(hw, port, &phy_time, &phc_time);
+ if (err)
+ goto err_unlock;
+
+ /* Calculate the amount required to add to the port time in order for
+ * it to match the PHC time.
+ *
+ * Note that the port adjustment is done using 2s complement
+ * arithmetic. This is convenient since it means that we can simply
+ * calculate the difference between the PHC time and the port time,
+ * and it will be interpreted correctly.
+ */
+ difference = phc_time - phy_time;
+
+ err = ice_ptp_prep_port_adj_e822(hw, port, (s64)difference);
+ if (err)
+ goto err_unlock;
+
+ err = ice_ptp_one_port_cmd(hw, port, ADJ_TIME);
+ if (err)
+ goto err_unlock;
+
+ /* Issue the sync to activate the time adjustment */
+ ice_ptp_exec_tmr_cmd(hw);
+
+ /* Re-capture the timer values to flush the command registers and
+ * verify that the time was properly adjusted.
+ */
+ err = ice_read_phy_and_phc_time_e822(hw, port, &phy_time, &phc_time);
+ if (err)
+ goto err_unlock;
+
+ dev_info(ice_hw_to_dev(hw),
+ "Port %u PHY time synced to PHC: 0x%016llX, 0x%016llX\n",
+ port, (unsigned long long)phy_time,
+ (unsigned long long)phc_time);
+
+ ice_ptp_unlock(hw);
+
+ return 0;
+
+err_unlock:
+ ice_ptp_unlock(hw);
+ return err;
+}
+
+/**
+ * ice_stop_phy_timer_e822 - Stop the PHY clock timer
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to stop
+ * @soft_reset: if true, hold the SOFT_RESET bit of P_REG_PS
+ *
+ * Stop the clock of a PHY port. This must be done as part of the flow to
+ * re-calibrate Tx and Rx timestamping offsets whenever the clock time is
+ * initialized or when link speed changes.
+ */
+int
+ice_stop_phy_timer_e822(struct ice_hw *hw, u8 port, bool soft_reset)
+{
+ int err;
+ u32 val;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_TX_OR, 0);
+ if (err)
+ return err;
+
+ err = ice_write_phy_reg_e822(hw, port, P_REG_RX_OR, 0);
+ if (err)
+ return err;
+
+ err = ice_read_phy_reg_e822(hw, port, P_REG_PS, &val);
+ if (err)
+ return err;
+
+ val &= ~P_REG_PS_START_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ val &= ~P_REG_PS_ENA_CLK_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ if (soft_reset) {
+ val |= P_REG_PS_SFT_RESET_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+ }
+
+ ice_debug(hw, ICE_DBG_PTP, "Disabled clock on PHY port %u\n", port);
+
+ return 0;
+}
+
+/**
+ * ice_start_phy_timer_e822 - Start the PHY clock timer
+ * @hw: pointer to the HW struct
+ * @port: the PHY port to start
+ * @bypass: if true, start the PHY in bypass mode
+ *
+ * Start the clock of a PHY port. This must be done as part of the flow to
+ * re-calibrate Tx and Rx timestamping offsets whenever the clock time is
+ * initialized or when link speed changes.
+ *
+ * Bypass mode enables timestamps immediately without waiting for Vernier
+ * calibration to complete. Hardware will still continue taking Vernier
+ * measurements on Tx or Rx of packets, but they will not be applied to
+ * timestamps. Use ice_phy_exit_bypass_e822 to exit bypass mode once hardware
+ * has completed offset calculation.
+ */
+int
+ice_start_phy_timer_e822(struct ice_hw *hw, u8 port, bool bypass)
+{
+ u32 lo, hi, val;
+ u64 incval;
+ u8 tmr_idx;
+ int err;
+
+ tmr_idx = ice_get_ptp_src_clock_index(hw);
+
+ err = ice_stop_phy_timer_e822(hw, port, false);
+ if (err)
+ return err;
+
+ ice_phy_cfg_lane_e822(hw, port);
+
+ err = ice_phy_cfg_uix_e822(hw, port);
+ if (err)
+ return err;
+
+ err = ice_phy_cfg_parpcs_e822(hw, port);
+ if (err)
+ return err;
+
+ lo = rd32(hw, GLTSYN_INCVAL_L(tmr_idx));
+ hi = rd32(hw, GLTSYN_INCVAL_H(tmr_idx));
+ incval = (u64)hi << 32 | lo;
+
+ err = ice_write_40b_phy_reg_e822(hw, port, P_REG_TIMETUS_L, incval);
+ if (err)
+ return err;
+
+ err = ice_ptp_one_port_cmd(hw, port, INIT_INCVAL);
+ if (err)
+ return err;
+
+ ice_ptp_exec_tmr_cmd(hw);
+
+ err = ice_read_phy_reg_e822(hw, port, P_REG_PS, &val);
+ if (err)
+ return err;
+
+ val |= P_REG_PS_SFT_RESET_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ val |= P_REG_PS_START_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ val &= ~P_REG_PS_SFT_RESET_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ err = ice_ptp_one_port_cmd(hw, port, INIT_INCVAL);
+ if (err)
+ return err;
+
+ ice_ptp_exec_tmr_cmd(hw);
+
+ val |= P_REG_PS_ENA_CLK_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ val |= P_REG_PS_LOAD_OFFSET_M;
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ ice_ptp_exec_tmr_cmd(hw);
+
+ err = ice_sync_phy_timer_e822(hw, port);
+ if (err)
+ return err;
+
+ if (bypass) {
+ val |= P_REG_PS_BYPASS_MODE_M;
+ /* Enter BYPASS mode, enabling timestamps immediately. */
+ err = ice_write_phy_reg_e822(hw, port, P_REG_PS, val);
+ if (err)
+ return err;
+
+ /* Program the fixed Tx offset */
+ err = ice_phy_cfg_fixed_tx_offset_e822(hw, port);
+ if (err)
+ return err;
+
+ /* Program the fixed Rx offset */
+ err = ice_phy_cfg_fixed_rx_offset_e822(hw, port);
+ if (err)
+ return err;
+ }
+
+ ice_debug(hw, ICE_DBG_PTP, "Enabled clock on PHY port %u\n", port);
+
+ return 0;
}
/* E810 functions
/* Device agnostic functions
*
- * The following functions implement useful behavior to hide the differences
- * between E810 and other devices. They call the device-specific
- * implementations where necessary.
- *
- * Currently, the driver only supports E810, but future work will enable
- * support for E822-based devices.
+ * The following functions implement shared behavior common to both E822 and
+ * E810 devices, possibly calling a device specific implementation where
+ * necessary.
*/
/**
wr32(hw, PFTSYN_SEM + (PFTSYN_SEM_BYTES * hw->pf_id), 0);
}
-/**
- * ice_ptp_src_cmd - Prepare source timer for a timer command
- * @hw: pointer to HW structure
- * @cmd: Timer command
- *
- * Prepare the source timer for an upcoming timer sync command.
- */
-static void ice_ptp_src_cmd(struct ice_hw *hw, enum ice_ptp_tmr_cmd cmd)
-{
- u32 cmd_val;
- u8 tmr_idx;
-
- tmr_idx = ice_get_ptp_src_clock_index(hw);
- cmd_val = tmr_idx << SEL_CPK_SRC;
-
- switch (cmd) {
- case INIT_TIME:
- cmd_val |= GLTSYN_CMD_INIT_TIME;
- break;
- case INIT_INCVAL:
- cmd_val |= GLTSYN_CMD_INIT_INCVAL;
- break;
- case ADJ_TIME:
- cmd_val |= GLTSYN_CMD_ADJ_TIME;
- break;
- case ADJ_TIME_AT_TIME:
- cmd_val |= GLTSYN_CMD_ADJ_INIT_TIME;
- break;
- case READ_TIME:
- cmd_val |= GLTSYN_CMD_READ_TIME;
- break;
- }
-
- wr32(hw, GLTSYN_CMD, cmd_val);
-}
-
/**
* ice_ptp_tmr_cmd - Prepare and trigger a timer sync command
* @hw: pointer to HW struct
ice_ptp_src_cmd(hw, cmd);
/* Next, prepare the ports */
- err = ice_ptp_port_cmd_e810(hw, cmd);
+ if (ice_is_e810(hw))
+ err = ice_ptp_port_cmd_e810(hw, cmd);
+ else
+ err = ice_ptp_port_cmd_e822(hw, cmd);
if (err) {
ice_debug(hw, ICE_DBG_PTP, "Failed to prepare PHY ports for timer command %u, err %d\n",
cmd, err);
return err;
}
- /* Write the sync command register to drive both source and PHY timer commands
- * synchronously
+ /* Write the sync command register to drive both source and PHY timer
+ * commands synchronously
*/
- wr32(hw, GLTSYN_CMD_SYNC, SYNC_EXEC_CMD);
+ ice_ptp_exec_tmr_cmd(hw);
return 0;
}
/* PHY timers */
/* Fill Rx and Tx ports and send msg to PHY */
- err = ice_ptp_prep_phy_time_e810(hw, time & 0xFFFFFFFF);
+ if (ice_is_e810(hw))
+ err = ice_ptp_prep_phy_time_e810(hw, time & 0xFFFFFFFF);
+ else
+ err = ice_ptp_prep_phy_time_e822(hw, time & 0xFFFFFFFF);
if (err)
return err;
wr32(hw, GLTSYN_SHADJ_L(tmr_idx), lower_32_bits(incval));
wr32(hw, GLTSYN_SHADJ_H(tmr_idx), upper_32_bits(incval));
- err = ice_ptp_prep_phy_incval_e810(hw, incval);
+ if (ice_is_e810(hw))
+ err = ice_ptp_prep_phy_incval_e810(hw, incval);
+ else
+ err = ice_ptp_prep_phy_incval_e822(hw, incval);
if (err)
return err;
wr32(hw, GLTSYN_SHADJ_L(tmr_idx), 0);
wr32(hw, GLTSYN_SHADJ_H(tmr_idx), adj);
- err = ice_ptp_prep_phy_adj_e810(hw, adj);
+ if (ice_is_e810(hw))
+ err = ice_ptp_prep_phy_adj_e810(hw, adj);
+ else
+ err = ice_ptp_prep_phy_adj_e822(hw, adj);
if (err)
return err;
* @idx: the timestamp index to read
* @tstamp: on return, the 40bit timestamp value
*
- * Read a 40bit timestamp value out of the timestamp block.
+ * Read a 40bit timestamp value out of the timestamp block. For E822 devices,
+ * the block is the quad to read from. For E810 devices, the block is the
+ * logical port to read from.
*/
int ice_read_phy_tstamp(struct ice_hw *hw, u8 block, u8 idx, u64 *tstamp)
{
- return ice_read_phy_tstamp_e810(hw, block, idx, tstamp);
+ if (ice_is_e810(hw))
+ return ice_read_phy_tstamp_e810(hw, block, idx, tstamp);
+ else
+ return ice_read_phy_tstamp_e822(hw, block, idx, tstamp);
}
/**
* @block: the block to read from
* @idx: the timestamp index to reset
*
- * Clear a timestamp, resetting its valid bit, from the timestamp block.
+ * Clear a timestamp, resetting its valid bit, from the timestamp block. For
+ * E822 devices, the block is the quad to clear from. For E810 devices, the
+ * block is the logical port to clear from.
*/
int ice_clear_phy_tstamp(struct ice_hw *hw, u8 block, u8 idx)
{
- return ice_clear_phy_tstamp_e810(hw, block, idx);
+ if (ice_is_e810(hw))
+ return ice_clear_phy_tstamp_e810(hw, block, idx);
+ else
+ return ice_clear_phy_tstamp_e822(hw, block, idx);
}
/* E810T SMA functions
/* Clear event err indications for auxiliary pins */
(void)rd32(hw, GLTSYN_STAT(src_idx));
- return ice_ptp_init_phc_e810(hw);
+ if (ice_is_e810(hw))
+ return ice_ptp_init_phc_e810(hw);
+ else
+ return ice_ptp_init_phc_e822(hw);
}
READ_TIME
};
+enum ice_ptp_serdes {
+ ICE_PTP_SERDES_1G,
+ ICE_PTP_SERDES_10G,
+ ICE_PTP_SERDES_25G,
+ ICE_PTP_SERDES_40G,
+ ICE_PTP_SERDES_50G,
+ ICE_PTP_SERDES_100G
+};
+
+enum ice_ptp_link_spd {
+ ICE_PTP_LNK_SPD_1G,
+ ICE_PTP_LNK_SPD_10G,
+ ICE_PTP_LNK_SPD_25G,
+ ICE_PTP_LNK_SPD_25G_RS,
+ ICE_PTP_LNK_SPD_40G,
+ ICE_PTP_LNK_SPD_50G,
+ ICE_PTP_LNK_SPD_50G_RS,
+ ICE_PTP_LNK_SPD_100G_RS,
+ NUM_ICE_PTP_LNK_SPD /* Must be last */
+};
+
+enum ice_ptp_fec_mode {
+ ICE_PTP_FEC_MODE_NONE,
+ ICE_PTP_FEC_MODE_CLAUSE74,
+ ICE_PTP_FEC_MODE_RS_FEC
+};
+
+/**
+ * struct ice_time_ref_info_e822
+ * @pll_freq: Frequency of PLL that drives timer ticks in Hz
+ * @nominal_incval: increment to generate nanoseconds in GLTSYN_TIME_L
+ * @pps_delay: propagation delay of the PPS output signal
+ *
+ * Characteristic information for the various TIME_REF sources possible in the
+ * E822 devices
+ */
+struct ice_time_ref_info_e822 {
+ u64 pll_freq;
+ u64 nominal_incval;
+ u8 pps_delay;
+};
+
+/**
+ * struct ice_vernier_info_e822
+ * @tx_par_clk: Frequency used to calculate P_REG_PAR_TX_TUS
+ * @rx_par_clk: Frequency used to calculate P_REG_PAR_RX_TUS
+ * @tx_pcs_clk: Frequency used to calculate P_REG_PCS_TX_TUS
+ * @rx_pcs_clk: Frequency used to calculate P_REG_PCS_RX_TUS
+ * @tx_desk_rsgb_par: Frequency used to calculate P_REG_DESK_PAR_TX_TUS
+ * @rx_desk_rsgb_par: Frequency used to calculate P_REG_DESK_PAR_RX_TUS
+ * @tx_desk_rsgb_pcs: Frequency used to calculate P_REG_DESK_PCS_TX_TUS
+ * @rx_desk_rsgb_pcs: Frequency used to calculate P_REG_DESK_PCS_RX_TUS
+ * @tx_fixed_delay: Fixed Tx latency measured in 1/100th nanoseconds
+ * @pmd_adj_divisor: Divisor used to calculate PDM alignment adjustment
+ * @rx_fixed_delay: Fixed Rx latency measured in 1/100th nanoseconds
+ *
+ * Table of constants used during as part of the Vernier calibration of the Tx
+ * and Rx timestamps. This includes frequency values used to compute TUs per
+ * PAR/PCS clock cycle, and static delay values measured during hardware
+ * design.
+ *
+ * Note that some values are not used for all link speeds, and the
+ * P_REG_DESK_PAR* registers may represent different clock markers at
+ * different link speeds, either the deskew marker for multi-lane link speeds
+ * or the Reed Solomon gearbox marker for RS-FEC.
+ */
+struct ice_vernier_info_e822 {
+ u32 tx_par_clk;
+ u32 rx_par_clk;
+ u32 tx_pcs_clk;
+ u32 rx_pcs_clk;
+ u32 tx_desk_rsgb_par;
+ u32 rx_desk_rsgb_par;
+ u32 tx_desk_rsgb_pcs;
+ u32 rx_desk_rsgb_pcs;
+ u32 tx_fixed_delay;
+ u32 pmd_adj_divisor;
+ u32 rx_fixed_delay;
+};
+
+/* Table of constants related to possible TIME_REF sources */
+extern const struct ice_time_ref_info_e822 e822_time_ref[NUM_ICE_TIME_REF_FREQ];
+
+/* Table of constants for Vernier calibration on E822 */
+extern const struct ice_vernier_info_e822 e822_vernier[NUM_ICE_PTP_LNK_SPD];
+
/* Increment value to generate nanoseconds in the GLTSYN_TIME_L register for
* the E810 devices. Based off of a PLL with an 812.5 MHz frequency.
*/
int ice_clear_phy_tstamp(struct ice_hw *hw, u8 block, u8 idx);
int ice_ptp_init_phc(struct ice_hw *hw);
+/* E822 family functions */
+int ice_read_phy_reg_e822(struct ice_hw *hw, u8 port, u16 offset, u32 *val);
+int ice_write_phy_reg_e822(struct ice_hw *hw, u8 port, u16 offset, u32 val);
+int ice_read_quad_reg_e822(struct ice_hw *hw, u8 quad, u16 offset, u32 *val);
+int ice_write_quad_reg_e822(struct ice_hw *hw, u8 quad, u16 offset, u32 val);
+int ice_ptp_prep_port_adj_e822(struct ice_hw *hw, u8 port, s64 time);
+
+/**
+ * ice_e822_time_ref - Get the current TIME_REF from capabilities
+ * @hw: pointer to the HW structure
+ *
+ * Returns the current TIME_REF from the capabilities structure.
+ */
+static inline enum ice_time_ref_freq ice_e822_time_ref(struct ice_hw *hw)
+{
+ return hw->func_caps.ts_func_info.time_ref;
+}
+
+/**
+ * ice_set_e822_time_ref - Set new TIME_REF
+ * @hw: pointer to the HW structure
+ * @time_ref: new TIME_REF to set
+ *
+ * Update the TIME_REF in the capabilities structure in response to some
+ * change, such as an update to the CGU registers.
+ */
+static inline void
+ice_set_e822_time_ref(struct ice_hw *hw, enum ice_time_ref_freq time_ref)
+{
+ hw->func_caps.ts_func_info.time_ref = time_ref;
+}
+
+static inline u64 ice_e822_pll_freq(enum ice_time_ref_freq time_ref)
+{
+ return e822_time_ref[time_ref].pll_freq;
+}
+
+static inline u64 ice_e822_nominal_incval(enum ice_time_ref_freq time_ref)
+{
+ return e822_time_ref[time_ref].nominal_incval;
+}
+
+static inline u64 ice_e822_pps_delay(enum ice_time_ref_freq time_ref)
+{
+ return e822_time_ref[time_ref].pps_delay;
+}
+
+/* E822 Vernier calibration functions */
+int ice_stop_phy_timer_e822(struct ice_hw *hw, u8 port, bool soft_reset);
+int ice_start_phy_timer_e822(struct ice_hw *hw, u8 port, bool bypass);
+
/* E810 family functions */
int ice_ptp_init_phy_e810(struct ice_hw *hw);
int ice_read_sma_ctrl_e810t(struct ice_hw *hw, u8 *data);
#define PFTSYN_SEM_BYTES 4
+#define ICE_PTP_CLOCK_INDEX_0 0x00
+#define ICE_PTP_CLOCK_INDEX_1 0x01
+
/* PHY timer commands */
#define SEL_CPK_SRC 8
+#define SEL_PHY_SRC 3
/* Time Sync command Definitions */
#define GLTSYN_CMD_INIT_TIME BIT(0)
#define GLTSYN_CMD_INIT_INCVAL BIT(1)
+#define GLTSYN_CMD_INIT_TIME_INCVAL (BIT(0) | BIT(1))
#define GLTSYN_CMD_ADJ_TIME BIT(2)
#define GLTSYN_CMD_ADJ_INIT_TIME (BIT(2) | BIT(3))
#define GLTSYN_CMD_READ_TIME BIT(7)
+/* PHY port Time Sync command definitions */
+#define PHY_CMD_INIT_TIME BIT(0)
+#define PHY_CMD_INIT_INCVAL BIT(1)
+#define PHY_CMD_ADJ_TIME (BIT(0) | BIT(1))
+#define PHY_CMD_ADJ_TIME_AT_TIME (BIT(0) | BIT(2))
+#define PHY_CMD_READ_TIME (BIT(0) | BIT(1) | BIT(2))
+
#define TS_CMD_MASK_E810 0xFF
+#define TS_CMD_MASK 0xF
#define SYNC_EXEC_CMD 0x3
+/* Macros to derive port low and high addresses on both quads */
+#define P_Q0_L(a, p) ((((a) + (0x2000 * (p)))) & 0xFFFF)
+#define P_Q0_H(a, p) ((((a) + (0x2000 * (p)))) >> 16)
+#define P_Q1_L(a, p) ((((a) - (0x2000 * ((p) - ICE_PORTS_PER_QUAD)))) & 0xFFFF)
+#define P_Q1_H(a, p) ((((a) - (0x2000 * ((p) - ICE_PORTS_PER_QUAD)))) >> 16)
+
+/* PHY QUAD register base addresses */
+#define Q_0_BASE 0x94000
+#define Q_1_BASE 0x114000
+
+/* Timestamp memory reset registers */
+#define Q_REG_TS_CTRL 0x618
+#define Q_REG_TS_CTRL_S 0
+#define Q_REG_TS_CTRL_M BIT(0)
+
+/* Timestamp availability status registers */
+#define Q_REG_TX_MEMORY_STATUS_L 0xCF0
+#define Q_REG_TX_MEMORY_STATUS_U 0xCF4
+
+/* Tx FIFO status registers */
+#define Q_REG_FIFO23_STATUS 0xCF8
+#define Q_REG_FIFO01_STATUS 0xCFC
+#define Q_REG_FIFO02_S 0
+#define Q_REG_FIFO02_M ICE_M(0x3FF, 0)
+#define Q_REG_FIFO13_S 10
+#define Q_REG_FIFO13_M ICE_M(0x3FF, 10)
+
+/* Interrupt control Config registers */
+#define Q_REG_TX_MEM_GBL_CFG 0xC08
+#define Q_REG_TX_MEM_GBL_CFG_LANE_TYPE_S 0
+#define Q_REG_TX_MEM_GBL_CFG_LANE_TYPE_M BIT(0)
+#define Q_REG_TX_MEM_GBL_CFG_TX_TYPE_S 1
+#define Q_REG_TX_MEM_GBL_CFG_TX_TYPE_M ICE_M(0xFF, 1)
+#define Q_REG_TX_MEM_GBL_CFG_INTR_THR_S 9
+#define Q_REG_TX_MEM_GBL_CFG_INTR_THR_M ICE_M(0x3F, 9)
+#define Q_REG_TX_MEM_GBL_CFG_INTR_ENA_S 15
+#define Q_REG_TX_MEM_GBL_CFG_INTR_ENA_M BIT(15)
+
+/* Tx Timestamp data registers */
+#define Q_REG_TX_MEMORY_BANK_START 0xA00
+
+/* PHY port register base addresses */
+#define P_0_BASE 0x80000
+#define P_4_BASE 0x106000
+
+/* Timestamp init registers */
+#define P_REG_RX_TIMER_INC_PRE_L 0x46C
+#define P_REG_RX_TIMER_INC_PRE_U 0x470
+#define P_REG_TX_TIMER_INC_PRE_L 0x44C
+#define P_REG_TX_TIMER_INC_PRE_U 0x450
+
+/* Timestamp match and adjust target registers */
+#define P_REG_RX_TIMER_CNT_ADJ_L 0x474
+#define P_REG_RX_TIMER_CNT_ADJ_U 0x478
+#define P_REG_TX_TIMER_CNT_ADJ_L 0x454
+#define P_REG_TX_TIMER_CNT_ADJ_U 0x458
+
+/* Timestamp capture registers */
+#define P_REG_RX_CAPTURE_L 0x4D8
+#define P_REG_RX_CAPTURE_U 0x4DC
+#define P_REG_TX_CAPTURE_L 0x4B4
+#define P_REG_TX_CAPTURE_U 0x4B8
+
+/* Timestamp PHY incval registers */
+#define P_REG_TIMETUS_L 0x410
+#define P_REG_TIMETUS_U 0x414
+
+#define P_REG_40B_LOW_M 0xFF
+#define P_REG_40B_HIGH_S 8
+
+/* PHY window length registers */
+#define P_REG_WL 0x40C
+
+#define PTP_VERNIER_WL 0x111ed
+
+/* PHY start registers */
+#define P_REG_PS 0x408
+#define P_REG_PS_START_S 0
+#define P_REG_PS_START_M BIT(0)
+#define P_REG_PS_BYPASS_MODE_S 1
+#define P_REG_PS_BYPASS_MODE_M BIT(1)
+#define P_REG_PS_ENA_CLK_S 2
+#define P_REG_PS_ENA_CLK_M BIT(2)
+#define P_REG_PS_LOAD_OFFSET_S 3
+#define P_REG_PS_LOAD_OFFSET_M BIT(3)
+#define P_REG_PS_SFT_RESET_S 11
+#define P_REG_PS_SFT_RESET_M BIT(11)
+
+/* PHY offset valid registers */
+#define P_REG_TX_OV_STATUS 0x4D4
+#define P_REG_TX_OV_STATUS_OV_S 0
+#define P_REG_TX_OV_STATUS_OV_M BIT(0)
+#define P_REG_RX_OV_STATUS 0x4F8
+#define P_REG_RX_OV_STATUS_OV_S 0
+#define P_REG_RX_OV_STATUS_OV_M BIT(0)
+
+/* PHY offset ready registers */
+#define P_REG_TX_OR 0x45C
+#define P_REG_RX_OR 0x47C
+
+/* PHY total offset registers */
+#define P_REG_TOTAL_RX_OFFSET_L 0x460
+#define P_REG_TOTAL_RX_OFFSET_U 0x464
+#define P_REG_TOTAL_TX_OFFSET_L 0x440
+#define P_REG_TOTAL_TX_OFFSET_U 0x444
+
+/* Timestamp PAR/PCS registers */
+#define P_REG_UIX66_10G_40G_L 0x480
+#define P_REG_UIX66_10G_40G_U 0x484
+#define P_REG_UIX66_25G_100G_L 0x488
+#define P_REG_UIX66_25G_100G_U 0x48C
+#define P_REG_DESK_PAR_RX_TUS_L 0x490
+#define P_REG_DESK_PAR_RX_TUS_U 0x494
+#define P_REG_DESK_PAR_TX_TUS_L 0x498
+#define P_REG_DESK_PAR_TX_TUS_U 0x49C
+#define P_REG_DESK_PCS_RX_TUS_L 0x4A0
+#define P_REG_DESK_PCS_RX_TUS_U 0x4A4
+#define P_REG_DESK_PCS_TX_TUS_L 0x4A8
+#define P_REG_DESK_PCS_TX_TUS_U 0x4AC
+#define P_REG_PAR_RX_TUS_L 0x420
+#define P_REG_PAR_RX_TUS_U 0x424
+#define P_REG_PAR_TX_TUS_L 0x428
+#define P_REG_PAR_TX_TUS_U 0x42C
+#define P_REG_PCS_RX_TUS_L 0x430
+#define P_REG_PCS_RX_TUS_U 0x434
+#define P_REG_PCS_TX_TUS_L 0x438
+#define P_REG_PCS_TX_TUS_U 0x43C
+#define P_REG_PAR_RX_TIME_L 0x4F0
+#define P_REG_PAR_RX_TIME_U 0x4F4
+#define P_REG_PAR_TX_TIME_L 0x4CC
+#define P_REG_PAR_TX_TIME_U 0x4D0
+#define P_REG_PAR_PCS_RX_OFFSET_L 0x4E8
+#define P_REG_PAR_PCS_RX_OFFSET_U 0x4EC
+#define P_REG_PAR_PCS_TX_OFFSET_L 0x4C4
+#define P_REG_PAR_PCS_TX_OFFSET_U 0x4C8
+#define P_REG_LINK_SPEED 0x4FC
+#define P_REG_LINK_SPEED_SERDES_S 0
+#define P_REG_LINK_SPEED_SERDES_M ICE_M(0x7, 0)
+#define P_REG_LINK_SPEED_FEC_MODE_S 3
+#define P_REG_LINK_SPEED_FEC_MODE_M ICE_M(0x3, 3)
+#define P_REG_LINK_SPEED_FEC_MODE(reg) \
+ (((reg) & P_REG_LINK_SPEED_FEC_MODE_M) >> \
+ P_REG_LINK_SPEED_FEC_MODE_S)
+
+/* PHY timestamp related registers */
+#define P_REG_PMD_ALIGNMENT 0x0FC
+#define P_REG_RX_80_TO_160_CNT 0x6FC
+#define P_REG_RX_80_TO_160_CNT_RXCYC_S 0
+#define P_REG_RX_80_TO_160_CNT_RXCYC_M BIT(0)
+#define P_REG_RX_40_TO_160_CNT 0x8FC
+#define P_REG_RX_40_TO_160_CNT_RXCYC_S 0
+#define P_REG_RX_40_TO_160_CNT_RXCYC_M ICE_M(0x3, 0)
+
+/* Rx FIFO status registers */
+#define P_REG_RX_OV_FS 0x4F8
+#define P_REG_RX_OV_FS_FIFO_STATUS_S 2
+#define P_REG_RX_OV_FS_FIFO_STATUS_M ICE_M(0x3FF, 2)
+
+/* Timestamp command registers */
+#define P_REG_TX_TMR_CMD 0x448
+#define P_REG_RX_TMR_CMD 0x468
+
/* E810 timesync enable register */
#define ETH_GLTSYN_ENA(_i) (0x03000348 + ((_i) * 4))
/* Timestamp block macros */
#define TS_LOW_M 0xFFFFFFFF
+#define TS_HIGH_M 0xFF
#define TS_HIGH_S 32
+#define TS_PHY_LOW_M 0xFF
+#define TS_PHY_HIGH_M 0xFFFFFFFF
+#define TS_PHY_HIGH_S 8
+
#define BYTES_PER_IDX_ADDR_L_U 8
+#define BYTES_PER_IDX_ADDR_L 4
+
+/* Internal PHY timestamp address */
+#define TS_L(a, idx) ((a) + ((idx) * BYTES_PER_IDX_ADDR_L_U))
+#define TS_H(a, idx) ((a) + ((idx) * BYTES_PER_IDX_ADDR_L_U + \
+ BYTES_PER_IDX_ADDR_L))
/* External PHY timestamp address */
#define TS_EXT(a, port, idx) ((a) + (0x1000 * (port)) + \
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