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1622 1623 1624 1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 1649 1650 1651 1652 1653 1654 1655 1656 1657 1658 1659 1660 1661 1662 1663 1664 1665 1666 1667 1668 1669 1670 1671 1672 1673 1674 1675 1676 1677 1678 1679 1680 1681 1682 1683 1684 1685 1686 1687 1688 1689 1690 1691 1692 1693 1694 1695 1696 1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 | // SPDX-License-Identifier: GPL-2.0-or-later /* * AppliedMicro X-Gene Multi-purpose PHY driver * * Copyright (c) 2014, Applied Micro Circuits Corporation * Author: Loc Ho <lho@apm.com> * Tuan Phan <tphan@apm.com> * Suman Tripathi <stripathi@apm.com> * * The APM X-Gene PHY consists of two PLL clock macro's (CMU) and lanes. * The first PLL clock macro is used for internal reference clock. The second * PLL clock macro is used to generate the clock for the PHY. This driver * configures the first PLL CMU, the second PLL CMU, and programs the PHY to * operate according to the mode of operation. The first PLL CMU is only * required if internal clock is enabled. * * Logical Layer Out Of HW module units: * * ----------------- * | Internal | |------| * | Ref PLL CMU |----| | ------------- --------- * ------------ ---- | MUX |-----|PHY PLL CMU|----| Serdes| * | | | | --------- * External Clock ------| | ------------- * |------| * * The Ref PLL CMU CSR (Configuration System Registers) is accessed * indirectly from the SDS offset at 0x2000. It is only required for * internal reference clock. * The PHY PLL CMU CSR is accessed indirectly from the SDS offset at 0x0000. * The Serdes CSR is accessed indirectly from the SDS offset at 0x0400. * * The Ref PLL CMU can be located within the same PHY IP or outside the PHY IP * due to shared Ref PLL CMU. For PHY with Ref PLL CMU shared with another IP, * it is located outside the PHY IP. This is the case for the PHY located * at 0x1f23a000 (SATA Port 4/5). For such PHY, another resource is required * to located the SDS/Ref PLL CMU module and its clock for that IP enabled. * * Currently, this driver only supports Gen3 SATA mode with external clock. */ #include <linux/module.h> #include <linux/platform_device.h> #include <linux/io.h> #include <linux/delay.h> #include <linux/phy/phy.h> #include <linux/clk.h> /* Max 2 lanes per a PHY unit */ #define MAX_LANE 2 /* Register offset inside the PHY */ #define SERDES_PLL_INDIRECT_OFFSET 0x0000 #define SERDES_PLL_REF_INDIRECT_OFFSET 0x2000 #define SERDES_INDIRECT_OFFSET 0x0400 #define SERDES_LANE_STRIDE 0x0200 /* Some default Serdes parameters */ #define DEFAULT_SATA_TXBOOST_GAIN { 0x1e, 0x1e, 0x1e } #define DEFAULT_SATA_TXEYEDIRECTION { 0x0, 0x0, 0x0 } #define DEFAULT_SATA_TXEYETUNING { 0xa, 0xa, 0xa } #define DEFAULT_SATA_SPD_SEL { 0x1, 0x3, 0x7 } #define DEFAULT_SATA_TXAMP { 0x8, 0x8, 0x8 } #define DEFAULT_SATA_TXCN1 { 0x2, 0x2, 0x2 } #define DEFAULT_SATA_TXCN2 { 0x0, 0x0, 0x0 } #define DEFAULT_SATA_TXCP1 { 0xa, 0xa, 0xa } #define SATA_SPD_SEL_GEN3 0x7 #define SATA_SPD_SEL_GEN2 0x3 #define SATA_SPD_SEL_GEN1 0x1 #define SSC_DISABLE 0 #define SSC_ENABLE 1 #define FBDIV_VAL_50M 0x77 #define REFDIV_VAL_50M 0x1 #define FBDIV_VAL_100M 0x3B #define REFDIV_VAL_100M 0x0 /* SATA Clock/Reset CSR */ #define SATACLKENREG 0x00000000 #define SATA0_CORE_CLKEN 0x00000002 #define SATA1_CORE_CLKEN 0x00000004 #define SATASRESETREG 0x00000004 #define SATA_MEM_RESET_MASK 0x00000020 #define SATA_MEM_RESET_RD(src) (((src) & 0x00000020) >> 5) #define SATA_SDS_RESET_MASK 0x00000004 #define SATA_CSR_RESET_MASK 0x00000001 #define SATA_CORE_RESET_MASK 0x00000002 #define SATA_PMCLK_RESET_MASK 0x00000010 #define SATA_PCLK_RESET_MASK 0x00000008 /* SDS CSR used for PHY Indirect access */ #define SATA_ENET_SDS_PCS_CTL0 0x00000000 #define REGSPEC_CFG_I_TX_WORDMODE0_SET(dst, src) \ (((dst) & ~0x00070000) | (((u32) (src) << 16) & 0x00070000)) #define REGSPEC_CFG_I_RX_WORDMODE0_SET(dst, src) \ (((dst) & ~0x00e00000) | (((u32) (src) << 21) & 0x00e00000)) #define SATA_ENET_SDS_CTL0 0x0000000c #define REGSPEC_CFG_I_CUSTOMER_PIN_MODE0_SET(dst, src) \ (((dst) & ~0x00007fff) | (((u32) (src)) & 0x00007fff)) #define SATA_ENET_SDS_CTL1 0x00000010 #define CFG_I_SPD_SEL_CDR_OVR1_SET(dst, src) \ (((dst) & ~0x0000000f) | (((u32) (src)) & 0x0000000f)) #define SATA_ENET_SDS_RST_CTL 0x00000024 #define SATA_ENET_SDS_IND_CMD_REG 0x0000003c #define CFG_IND_WR_CMD_MASK 0x00000001 #define CFG_IND_RD_CMD_MASK 0x00000002 #define CFG_IND_CMD_DONE_MASK 0x00000004 #define CFG_IND_ADDR_SET(dst, src) \ (((dst) & ~0x003ffff0) | (((u32) (src) << 4) & 0x003ffff0)) #define SATA_ENET_SDS_IND_RDATA_REG 0x00000040 #define SATA_ENET_SDS_IND_WDATA_REG 0x00000044 #define SATA_ENET_CLK_MACRO_REG 0x0000004c #define I_RESET_B_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src)) & 0x00000001)) #define I_PLL_FBDIV_SET(dst, src) \ (((dst) & ~0x001ff000) | (((u32) (src) << 12) & 0x001ff000)) #define I_CUSTOMEROV_SET(dst, src) \ (((dst) & ~0x00000f80) | (((u32) (src) << 7) & 0x00000f80)) #define O_PLL_LOCK_RD(src) (((src) & 0x40000000) >> 30) #define O_PLL_READY_RD(src) (((src) & 0x80000000) >> 31) /* PLL Clock Macro Unit (CMU) CSR accessing from SDS indirectly */ #define CMU_REG0 0x00000 #define CMU_REG0_PLL_REF_SEL_MASK 0x00002000 #define CMU_REG0_PLL_REF_SEL_SET(dst, src) \ (((dst) & ~0x00002000) | (((u32) (src) << 13) & 0x00002000)) #define CMU_REG0_PDOWN_MASK 0x00004000 #define CMU_REG0_CAL_COUNT_RESOL_SET(dst, src) \ (((dst) & ~0x000000e0) | (((u32) (src) << 5) & 0x000000e0)) #define CMU_REG1 0x00002 #define CMU_REG1_PLL_CP_SET(dst, src) \ (((dst) & ~0x00003c00) | (((u32) (src) << 10) & 0x00003c00)) #define CMU_REG1_PLL_MANUALCAL_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define CMU_REG1_PLL_CP_SEL_SET(dst, src) \ (((dst) & ~0x000003e0) | (((u32) (src) << 5) & 0x000003e0)) #define CMU_REG1_REFCLK_CMOS_SEL_MASK 0x00000001 #define CMU_REG1_REFCLK_CMOS_SEL_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src) << 0) & 0x00000001)) #define CMU_REG2 0x00004 #define CMU_REG2_PLL_REFDIV_SET(dst, src) \ (((dst) & ~0x0000c000) | (((u32) (src) << 14) & 0x0000c000)) #define CMU_REG2_PLL_LFRES_SET(dst, src) \ (((dst) & ~0x0000001e) | (((u32) (src) << 1) & 0x0000001e)) #define CMU_REG2_PLL_FBDIV_SET(dst, src) \ (((dst) & ~0x00003fe0) | (((u32) (src) << 5) & 0x00003fe0)) #define CMU_REG3 0x00006 #define CMU_REG3_VCOVARSEL_SET(dst, src) \ (((dst) & ~0x0000000f) | (((u32) (src) << 0) & 0x0000000f)) #define CMU_REG3_VCO_MOMSEL_INIT_SET(dst, src) \ (((dst) & ~0x000003f0) | (((u32) (src) << 4) & 0x000003f0)) #define CMU_REG3_VCO_MANMOMSEL_SET(dst, src) \ (((dst) & ~0x0000fc00) | (((u32) (src) << 10) & 0x0000fc00)) #define CMU_REG4 0x00008 #define CMU_REG5 0x0000a #define CMU_REG5_PLL_LFSMCAP_SET(dst, src) \ (((dst) & ~0x0000c000) | (((u32) (src) << 14) & 0x0000c000)) #define CMU_REG5_PLL_LOCK_RESOLUTION_SET(dst, src) \ (((dst) & ~0x0000000e) | (((u32) (src) << 1) & 0x0000000e)) #define CMU_REG5_PLL_LFCAP_SET(dst, src) \ (((dst) & ~0x00003000) | (((u32) (src) << 12) & 0x00003000)) #define CMU_REG5_PLL_RESETB_MASK 0x00000001 #define CMU_REG6 0x0000c #define CMU_REG6_PLL_VREGTRIM_SET(dst, src) \ (((dst) & ~0x00000600) | (((u32) (src) << 9) & 0x00000600)) #define CMU_REG6_MAN_PVT_CAL_SET(dst, src) \ (((dst) & ~0x00000004) | (((u32) (src) << 2) & 0x00000004)) #define CMU_REG7 0x0000e #define CMU_REG7_PLL_CALIB_DONE_RD(src) ((0x00004000 & (u32) (src)) >> 14) #define CMU_REG7_VCO_CAL_FAIL_RD(src) ((0x00000c00 & (u32) (src)) >> 10) #define CMU_REG8 0x00010 #define CMU_REG9 0x00012 #define CMU_REG9_WORD_LEN_8BIT 0x000 #define CMU_REG9_WORD_LEN_10BIT 0x001 #define CMU_REG9_WORD_LEN_16BIT 0x002 #define CMU_REG9_WORD_LEN_20BIT 0x003 #define CMU_REG9_WORD_LEN_32BIT 0x004 #define CMU_REG9_WORD_LEN_40BIT 0x005 #define CMU_REG9_WORD_LEN_64BIT 0x006 #define CMU_REG9_WORD_LEN_66BIT 0x007 #define CMU_REG9_TX_WORD_MODE_CH1_SET(dst, src) \ (((dst) & ~0x00000380) | (((u32) (src) << 7) & 0x00000380)) #define CMU_REG9_TX_WORD_MODE_CH0_SET(dst, src) \ (((dst) & ~0x00000070) | (((u32) (src) << 4) & 0x00000070)) #define CMU_REG9_PLL_POST_DIVBY2_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define CMU_REG9_VBG_BYPASSB_SET(dst, src) \ (((dst) & ~0x00000004) | (((u32) (src) << 2) & 0x00000004)) #define CMU_REG9_IGEN_BYPASS_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define CMU_REG10 0x00014 #define CMU_REG10_VREG_REFSEL_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src) << 0) & 0x00000001)) #define CMU_REG11 0x00016 #define CMU_REG12 0x00018 #define CMU_REG12_STATE_DELAY9_SET(dst, src) \ (((dst) & ~0x000000f0) | (((u32) (src) << 4) & 0x000000f0)) #define CMU_REG13 0x0001a #define CMU_REG14 0x0001c #define CMU_REG15 0x0001e #define CMU_REG16 0x00020 #define CMU_REG16_PVT_DN_MAN_ENA_MASK 0x00000001 #define CMU_REG16_PVT_UP_MAN_ENA_MASK 0x00000002 #define CMU_REG16_VCOCAL_WAIT_BTW_CODE_SET(dst, src) \ (((dst) & ~0x0000001c) | (((u32) (src) << 2) & 0x0000001c)) #define CMU_REG16_CALIBRATION_DONE_OVERRIDE_SET(dst, src) \ (((dst) & ~0x00000040) | (((u32) (src) << 6) & 0x00000040)) #define CMU_REG16_BYPASS_PLL_LOCK_SET(dst, src) \ (((dst) & ~0x00000020) | (((u32) (src) << 5) & 0x00000020)) #define CMU_REG17 0x00022 #define CMU_REG17_PVT_CODE_R2A_SET(dst, src) \ (((dst) & ~0x00007f00) | (((u32) (src) << 8) & 0x00007f00)) #define CMU_REG17_RESERVED_7_SET(dst, src) \ (((dst) & ~0x000000e0) | (((u32) (src) << 5) & 0x000000e0)) #define CMU_REG17_PVT_TERM_MAN_ENA_MASK 0x00008000 #define CMU_REG18 0x00024 #define CMU_REG19 0x00026 #define CMU_REG20 0x00028 #define CMU_REG21 0x0002a #define CMU_REG22 0x0002c #define CMU_REG23 0x0002e #define CMU_REG24 0x00030 #define CMU_REG25 0x00032 #define CMU_REG26 0x00034 #define CMU_REG26_FORCE_PLL_LOCK_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src) << 0) & 0x00000001)) #define CMU_REG27 0x00036 #define CMU_REG28 0x00038 #define CMU_REG29 0x0003a #define CMU_REG30 0x0003c #define CMU_REG30_LOCK_COUNT_SET(dst, src) \ (((dst) & ~0x00000006) | (((u32) (src) << 1) & 0x00000006)) #define CMU_REG30_PCIE_MODE_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define CMU_REG31 0x0003e #define CMU_REG32 0x00040 #define CMU_REG32_FORCE_VCOCAL_START_MASK 0x00004000 #define CMU_REG32_PVT_CAL_WAIT_SEL_SET(dst, src) \ (((dst) & ~0x00000006) | (((u32) (src) << 1) & 0x00000006)) #define CMU_REG32_IREF_ADJ_SET(dst, src) \ (((dst) & ~0x00000180) | (((u32) (src) << 7) & 0x00000180)) #define CMU_REG33 0x00042 #define CMU_REG34 0x00044 #define CMU_REG34_VCO_CAL_VTH_LO_MAX_SET(dst, src) \ (((dst) & ~0x0000000f) | (((u32) (src) << 0) & 0x0000000f)) #define CMU_REG34_VCO_CAL_VTH_HI_MAX_SET(dst, src) \ (((dst) & ~0x00000f00) | (((u32) (src) << 8) & 0x00000f00)) #define CMU_REG34_VCO_CAL_VTH_LO_MIN_SET(dst, src) \ (((dst) & ~0x000000f0) | (((u32) (src) << 4) & 0x000000f0)) #define CMU_REG34_VCO_CAL_VTH_HI_MIN_SET(dst, src) \ (((dst) & ~0x0000f000) | (((u32) (src) << 12) & 0x0000f000)) #define CMU_REG35 0x00046 #define CMU_REG35_PLL_SSC_MOD_SET(dst, src) \ (((dst) & ~0x0000fe00) | (((u32) (src) << 9) & 0x0000fe00)) #define CMU_REG36 0x00048 #define CMU_REG36_PLL_SSC_EN_SET(dst, src) \ (((dst) & ~0x00000010) | (((u32) (src) << 4) & 0x00000010)) #define CMU_REG36_PLL_SSC_VSTEP_SET(dst, src) \ (((dst) & ~0x0000ffc0) | (((u32) (src) << 6) & 0x0000ffc0)) #define CMU_REG36_PLL_SSC_DSMSEL_SET(dst, src) \ (((dst) & ~0x00000020) | (((u32) (src) << 5) & 0x00000020)) #define CMU_REG37 0x0004a #define CMU_REG38 0x0004c #define CMU_REG39 0x0004e /* PHY lane CSR accessing from SDS indirectly */ #define RXTX_REG0 0x000 #define RXTX_REG0_CTLE_EQ_HR_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG0_CTLE_EQ_QR_SET(dst, src) \ (((dst) & ~0x000007c0) | (((u32) (src) << 6) & 0x000007c0)) #define RXTX_REG0_CTLE_EQ_FR_SET(dst, src) \ (((dst) & ~0x0000003e) | (((u32) (src) << 1) & 0x0000003e)) #define RXTX_REG1 0x002 #define RXTX_REG1_RXACVCM_SET(dst, src) \ (((dst) & ~0x0000f000) | (((u32) (src) << 12) & 0x0000f000)) #define RXTX_REG1_CTLE_EQ_SET(dst, src) \ (((dst) & ~0x00000f80) | (((u32) (src) << 7) & 0x00000f80)) #define RXTX_REG1_RXVREG1_SET(dst, src) \ (((dst) & ~0x00000060) | (((u32) (src) << 5) & 0x00000060)) #define RXTX_REG1_RXIREF_ADJ_SET(dst, src) \ (((dst) & ~0x00000006) | (((u32) (src) << 1) & 0x00000006)) #define RXTX_REG2 0x004 #define RXTX_REG2_VTT_ENA_SET(dst, src) \ (((dst) & ~0x00000100) | (((u32) (src) << 8) & 0x00000100)) #define RXTX_REG2_TX_FIFO_ENA_SET(dst, src) \ (((dst) & ~0x00000020) | (((u32) (src) << 5) & 0x00000020)) #define RXTX_REG2_VTT_SEL_SET(dst, src) \ (((dst) & ~0x000000c0) | (((u32) (src) << 6) & 0x000000c0)) #define RXTX_REG4 0x008 #define RXTX_REG4_TX_LOOPBACK_BUF_EN_MASK 0x00000040 #define RXTX_REG4_TX_DATA_RATE_SET(dst, src) \ (((dst) & ~0x0000c000) | (((u32) (src) << 14) & 0x0000c000)) #define RXTX_REG4_TX_WORD_MODE_SET(dst, src) \ (((dst) & ~0x00003800) | (((u32) (src) << 11) & 0x00003800)) #define RXTX_REG5 0x00a #define RXTX_REG5_TX_CN1_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG5_TX_CP1_SET(dst, src) \ (((dst) & ~0x000007e0) | (((u32) (src) << 5) & 0x000007e0)) #define RXTX_REG5_TX_CN2_SET(dst, src) \ (((dst) & ~0x0000001f) | (((u32) (src) << 0) & 0x0000001f)) #define RXTX_REG6 0x00c #define RXTX_REG6_TXAMP_CNTL_SET(dst, src) \ (((dst) & ~0x00000780) | (((u32) (src) << 7) & 0x00000780)) #define RXTX_REG6_TXAMP_ENA_SET(dst, src) \ (((dst) & ~0x00000040) | (((u32) (src) << 6) & 0x00000040)) #define RXTX_REG6_RX_BIST_ERRCNT_RD_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src) << 0) & 0x00000001)) #define RXTX_REG6_TX_IDLE_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define RXTX_REG6_RX_BIST_RESYNC_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define RXTX_REG7 0x00e #define RXTX_REG7_RESETB_RXD_MASK 0x00000100 #define RXTX_REG7_RESETB_RXA_MASK 0x00000080 #define RXTX_REG7_BIST_ENA_RX_SET(dst, src) \ (((dst) & ~0x00000040) | (((u32) (src) << 6) & 0x00000040)) #define RXTX_REG7_RX_WORD_MODE_SET(dst, src) \ (((dst) & ~0x00003800) | (((u32) (src) << 11) & 0x00003800)) #define RXTX_REG8 0x010 #define RXTX_REG8_CDR_LOOP_ENA_SET(dst, src) \ (((dst) & ~0x00004000) | (((u32) (src) << 14) & 0x00004000)) #define RXTX_REG8_CDR_BYPASS_RXLOS_SET(dst, src) \ (((dst) & ~0x00000800) | (((u32) (src) << 11) & 0x00000800)) #define RXTX_REG8_SSC_ENABLE_SET(dst, src) \ (((dst) & ~0x00000200) | (((u32) (src) << 9) & 0x00000200)) #define RXTX_REG8_SD_VREF_SET(dst, src) \ (((dst) & ~0x000000f0) | (((u32) (src) << 4) & 0x000000f0)) #define RXTX_REG8_SD_DISABLE_SET(dst, src) \ (((dst) & ~0x00000100) | (((u32) (src) << 8) & 0x00000100)) #define RXTX_REG7 0x00e #define RXTX_REG7_RESETB_RXD_SET(dst, src) \ (((dst) & ~0x00000100) | (((u32) (src) << 8) & 0x00000100)) #define RXTX_REG7_RESETB_RXA_SET(dst, src) \ (((dst) & ~0x00000080) | (((u32) (src) << 7) & 0x00000080)) #define RXTX_REG7_LOOP_BACK_ENA_CTLE_MASK 0x00004000 #define RXTX_REG7_LOOP_BACK_ENA_CTLE_SET(dst, src) \ (((dst) & ~0x00004000) | (((u32) (src) << 14) & 0x00004000)) #define RXTX_REG11 0x016 #define RXTX_REG11_PHASE_ADJUST_LIMIT_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG12 0x018 #define RXTX_REG12_LATCH_OFF_ENA_SET(dst, src) \ (((dst) & ~0x00002000) | (((u32) (src) << 13) & 0x00002000)) #define RXTX_REG12_SUMOS_ENABLE_SET(dst, src) \ (((dst) & ~0x00000004) | (((u32) (src) << 2) & 0x00000004)) #define RXTX_REG12_RX_DET_TERM_ENABLE_MASK 0x00000002 #define RXTX_REG12_RX_DET_TERM_ENABLE_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define RXTX_REG13 0x01a #define RXTX_REG14 0x01c #define RXTX_REG14_CLTE_LATCAL_MAN_PROG_SET(dst, src) \ (((dst) & ~0x0000003f) | (((u32) (src) << 0) & 0x0000003f)) #define RXTX_REG14_CTLE_LATCAL_MAN_ENA_SET(dst, src) \ (((dst) & ~0x00000040) | (((u32) (src) << 6) & 0x00000040)) #define RXTX_REG26 0x034 #define RXTX_REG26_PERIOD_ERROR_LATCH_SET(dst, src) \ (((dst) & ~0x00003800) | (((u32) (src) << 11) & 0x00003800)) #define RXTX_REG26_BLWC_ENA_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define RXTX_REG21 0x02a #define RXTX_REG21_DO_LATCH_CALOUT_RD(src) ((0x0000fc00 & (u32) (src)) >> 10) #define RXTX_REG21_XO_LATCH_CALOUT_RD(src) ((0x000003f0 & (u32) (src)) >> 4) #define RXTX_REG21_LATCH_CAL_FAIL_ODD_RD(src) ((0x0000000f & (u32)(src))) #define RXTX_REG22 0x02c #define RXTX_REG22_SO_LATCH_CALOUT_RD(src) ((0x000003f0 & (u32) (src)) >> 4) #define RXTX_REG22_EO_LATCH_CALOUT_RD(src) ((0x0000fc00 & (u32) (src)) >> 10) #define RXTX_REG22_LATCH_CAL_FAIL_EVEN_RD(src) ((0x0000000f & (u32)(src))) #define RXTX_REG23 0x02e #define RXTX_REG23_DE_LATCH_CALOUT_RD(src) ((0x0000fc00 & (u32) (src)) >> 10) #define RXTX_REG23_XE_LATCH_CALOUT_RD(src) ((0x000003f0 & (u32) (src)) >> 4) #define RXTX_REG24 0x030 #define RXTX_REG24_EE_LATCH_CALOUT_RD(src) ((0x0000fc00 & (u32) (src)) >> 10) #define RXTX_REG24_SE_LATCH_CALOUT_RD(src) ((0x000003f0 & (u32) (src)) >> 4) #define RXTX_REG27 0x036 #define RXTX_REG28 0x038 #define RXTX_REG31 0x03e #define RXTX_REG38 0x04c #define RXTX_REG38_CUSTOMER_PINMODE_INV_SET(dst, src) \ (((dst) & 0x0000fffe) | (((u32) (src) << 1) & 0x0000fffe)) #define RXTX_REG39 0x04e #define RXTX_REG40 0x050 #define RXTX_REG41 0x052 #define RXTX_REG42 0x054 #define RXTX_REG43 0x056 #define RXTX_REG44 0x058 #define RXTX_REG45 0x05a #define RXTX_REG46 0x05c #define RXTX_REG47 0x05e #define RXTX_REG48 0x060 #define RXTX_REG49 0x062 #define RXTX_REG50 0x064 #define RXTX_REG51 0x066 #define RXTX_REG52 0x068 #define RXTX_REG53 0x06a #define RXTX_REG54 0x06c #define RXTX_REG55 0x06e #define RXTX_REG61 0x07a #define RXTX_REG61_ISCAN_INBERT_SET(dst, src) \ (((dst) & ~0x00000010) | (((u32) (src) << 4) & 0x00000010)) #define RXTX_REG61_LOADFREQ_SHIFT_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define RXTX_REG61_EYE_COUNT_WIDTH_SEL_SET(dst, src) \ (((dst) & ~0x000000c0) | (((u32) (src) << 6) & 0x000000c0)) #define RXTX_REG61_SPD_SEL_CDR_SET(dst, src) \ (((dst) & ~0x00003c00) | (((u32) (src) << 10) & 0x00003c00)) #define RXTX_REG62 0x07c #define RXTX_REG62_PERIOD_H1_QLATCH_SET(dst, src) \ (((dst) & ~0x00003800) | (((u32) (src) << 11) & 0x00003800)) #define RXTX_REG81 0x0a2 #define RXTX_REG89_MU_TH7_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG89_MU_TH8_SET(dst, src) \ (((dst) & ~0x000007c0) | (((u32) (src) << 6) & 0x000007c0)) #define RXTX_REG89_MU_TH9_SET(dst, src) \ (((dst) & ~0x0000003e) | (((u32) (src) << 1) & 0x0000003e)) #define RXTX_REG96 0x0c0 #define RXTX_REG96_MU_FREQ1_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG96_MU_FREQ2_SET(dst, src) \ (((dst) & ~0x000007c0) | (((u32) (src) << 6) & 0x000007c0)) #define RXTX_REG96_MU_FREQ3_SET(dst, src) \ (((dst) & ~0x0000003e) | (((u32) (src) << 1) & 0x0000003e)) #define RXTX_REG99 0x0c6 #define RXTX_REG99_MU_PHASE1_SET(dst, src) \ (((dst) & ~0x0000f800) | (((u32) (src) << 11) & 0x0000f800)) #define RXTX_REG99_MU_PHASE2_SET(dst, src) \ (((dst) & ~0x000007c0) | (((u32) (src) << 6) & 0x000007c0)) #define RXTX_REG99_MU_PHASE3_SET(dst, src) \ (((dst) & ~0x0000003e) | (((u32) (src) << 1) & 0x0000003e)) #define RXTX_REG102 0x0cc #define RXTX_REG102_FREQLOOP_LIMIT_SET(dst, src) \ (((dst) & ~0x00000060) | (((u32) (src) << 5) & 0x00000060)) #define RXTX_REG114 0x0e4 #define RXTX_REG121 0x0f2 #define RXTX_REG121_SUMOS_CAL_CODE_RD(src) ((0x0000003e & (u32)(src)) >> 0x1) #define RXTX_REG125 0x0fa #define RXTX_REG125_PQ_REG_SET(dst, src) \ (((dst) & ~0x0000fe00) | (((u32) (src) << 9) & 0x0000fe00)) #define RXTX_REG125_SIGN_PQ_SET(dst, src) \ (((dst) & ~0x00000100) | (((u32) (src) << 8) & 0x00000100)) #define RXTX_REG125_SIGN_PQ_2C_SET(dst, src) \ (((dst) & ~0x00000080) | (((u32) (src) << 7) & 0x00000080)) #define RXTX_REG125_PHZ_MANUALCODE_SET(dst, src) \ (((dst) & ~0x0000007c) | (((u32) (src) << 2) & 0x0000007c)) #define RXTX_REG125_PHZ_MANUAL_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define RXTX_REG127 0x0fe #define RXTX_REG127_FORCE_SUM_CAL_START_MASK 0x00000002 #define RXTX_REG127_FORCE_LAT_CAL_START_MASK 0x00000004 #define RXTX_REG127_FORCE_SUM_CAL_START_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define RXTX_REG127_FORCE_LAT_CAL_START_SET(dst, src) \ (((dst) & ~0x00000004) | (((u32) (src) << 2) & 0x00000004)) #define RXTX_REG127_LATCH_MAN_CAL_ENA_SET(dst, src) \ (((dst) & ~0x00000008) | (((u32) (src) << 3) & 0x00000008)) #define RXTX_REG127_DO_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x0000fc00) | (((u32) (src) << 10) & 0x0000fc00)) #define RXTX_REG127_XO_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x000003f0) | (((u32) (src) << 4) & 0x000003f0)) #define RXTX_REG128 0x100 #define RXTX_REG128_LATCH_CAL_WAIT_SEL_SET(dst, src) \ (((dst) & ~0x0000000c) | (((u32) (src) << 2) & 0x0000000c)) #define RXTX_REG128_EO_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x0000fc00) | (((u32) (src) << 10) & 0x0000fc00)) #define RXTX_REG128_SO_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x000003f0) | (((u32) (src) << 4) & 0x000003f0)) #define RXTX_REG129 0x102 #define RXTX_REG129_DE_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x0000fc00) | (((u32) (src) << 10) & 0x0000fc00)) #define RXTX_REG129_XE_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x000003f0) | (((u32) (src) << 4) & 0x000003f0)) #define RXTX_REG130 0x104 #define RXTX_REG130_EE_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x0000fc00) | (((u32) (src) << 10) & 0x0000fc00)) #define RXTX_REG130_SE_LATCH_MANCAL_SET(dst, src) \ (((dst) & ~0x000003f0) | (((u32) (src) << 4) & 0x000003f0)) #define RXTX_REG145 0x122 #define RXTX_REG145_TX_IDLE_SATA_SET(dst, src) \ (((dst) & ~0x00000001) | (((u32) (src) << 0) & 0x00000001)) #define RXTX_REG145_RXES_ENA_SET(dst, src) \ (((dst) & ~0x00000002) | (((u32) (src) << 1) & 0x00000002)) #define RXTX_REG145_RXDFE_CONFIG_SET(dst, src) \ (((dst) & ~0x0000c000) | (((u32) (src) << 14) & 0x0000c000)) #define RXTX_REG145_RXVWES_LATENA_SET(dst, src) \ (((dst) & ~0x00000004) | (((u32) (src) << 2) & 0x00000004)) #define RXTX_REG147 0x126 #define RXTX_REG148 0x128 /* Clock macro type */ enum cmu_type_t { REF_CMU = 0, /* Clock macro is the internal reference clock */ PHY_CMU = 1, /* Clock macro is the PLL for the Serdes */ }; enum mux_type_t { MUX_SELECT_ATA = 0, /* Switch the MUX to ATA */ MUX_SELECT_SGMMII = 0, /* Switch the MUX to SGMII */ }; enum clk_type_t { CLK_EXT_DIFF = 0, /* External differential */ CLK_INT_DIFF = 1, /* Internal differential */ CLK_INT_SING = 2, /* Internal single ended */ }; enum xgene_phy_mode { MODE_SATA = 0, /* List them for simple reference */ MODE_SGMII = 1, MODE_PCIE = 2, MODE_USB = 3, MODE_XFI = 4, MODE_MAX }; struct xgene_sata_override_param { u32 speed[MAX_LANE]; /* Index for override parameter per lane */ u32 txspeed[3]; /* Tx speed */ u32 txboostgain[MAX_LANE*3]; /* Tx freq boost and gain control */ u32 txeyetuning[MAX_LANE*3]; /* Tx eye tuning */ u32 txeyedirection[MAX_LANE*3]; /* Tx eye tuning direction */ u32 txamplitude[MAX_LANE*3]; /* Tx amplitude control */ u32 txprecursor_cn1[MAX_LANE*3]; /* Tx emphasis taps 1st pre-cursor */ u32 txprecursor_cn2[MAX_LANE*3]; /* Tx emphasis taps 2nd pre-cursor */ u32 txpostcursor_cp1[MAX_LANE*3]; /* Tx emphasis taps post-cursor */ }; struct xgene_phy_ctx { struct device *dev; struct phy *phy; enum xgene_phy_mode mode; /* Mode of operation */ enum clk_type_t clk_type; /* Input clock selection */ void __iomem *sds_base; /* PHY CSR base addr */ struct clk *clk; /* Optional clock */ /* Override Serdes parameters */ struct xgene_sata_override_param sata_param; }; /* * For chip earlier than A3 version, enable this flag. * To enable, pass boot argument phy_xgene.preA3Chip=1 */ static int preA3Chip; MODULE_PARM_DESC(preA3Chip, "Enable pre-A3 chip support (1=enable 0=disable)"); module_param_named(preA3Chip, preA3Chip, int, 0444); static void sds_wr(void __iomem *csr_base, u32 indirect_cmd_reg, u32 indirect_data_reg, u32 addr, u32 data) { unsigned long deadline = jiffies + HZ; u32 val; u32 cmd; cmd = CFG_IND_WR_CMD_MASK | CFG_IND_CMD_DONE_MASK; cmd = CFG_IND_ADDR_SET(cmd, addr); writel(data, csr_base + indirect_data_reg); readl(csr_base + indirect_data_reg); /* Force a barrier */ writel(cmd, csr_base + indirect_cmd_reg); readl(csr_base + indirect_cmd_reg); /* Force a barrier */ do { val = readl(csr_base + indirect_cmd_reg); } while (!(val & CFG_IND_CMD_DONE_MASK) && time_before(jiffies, deadline)); if (!(val & CFG_IND_CMD_DONE_MASK)) pr_err("SDS WR timeout at 0x%p offset 0x%08X value 0x%08X\n", csr_base + indirect_cmd_reg, addr, data); } static void sds_rd(void __iomem *csr_base, u32 indirect_cmd_reg, u32 indirect_data_reg, u32 addr, u32 *data) { unsigned long deadline = jiffies + HZ; u32 val; u32 cmd; cmd = CFG_IND_RD_CMD_MASK | CFG_IND_CMD_DONE_MASK; cmd = CFG_IND_ADDR_SET(cmd, addr); writel(cmd, csr_base + indirect_cmd_reg); readl(csr_base + indirect_cmd_reg); /* Force a barrier */ do { val = readl(csr_base + indirect_cmd_reg); } while (!(val & CFG_IND_CMD_DONE_MASK) && time_before(jiffies, deadline)); *data = readl(csr_base + indirect_data_reg); if (!(val & CFG_IND_CMD_DONE_MASK)) pr_err("SDS WR timeout at 0x%p offset 0x%08X value 0x%08X\n", csr_base + indirect_cmd_reg, addr, *data); } static void cmu_wr(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, u32 reg, u32 data) { void __iomem *sds_base = ctx->sds_base; u32 val; if (cmu_type == REF_CMU) reg += SERDES_PLL_REF_INDIRECT_OFFSET; else reg += SERDES_PLL_INDIRECT_OFFSET; sds_wr(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_WDATA_REG, reg, data); sds_rd(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_RDATA_REG, reg, &val); pr_debug("CMU WR addr 0x%X value 0x%08X <-> 0x%08X\n", reg, data, val); } static void cmu_rd(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, u32 reg, u32 *data) { void __iomem *sds_base = ctx->sds_base; if (cmu_type == REF_CMU) reg += SERDES_PLL_REF_INDIRECT_OFFSET; else reg += SERDES_PLL_INDIRECT_OFFSET; sds_rd(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_RDATA_REG, reg, data); pr_debug("CMU RD addr 0x%X value 0x%08X\n", reg, *data); } static void cmu_toggle1to0(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, u32 reg, u32 bits) { u32 val; cmu_rd(ctx, cmu_type, reg, &val); val |= bits; cmu_wr(ctx, cmu_type, reg, val); cmu_rd(ctx, cmu_type, reg, &val); val &= ~bits; cmu_wr(ctx, cmu_type, reg, val); } static void cmu_clrbits(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, u32 reg, u32 bits) { u32 val; cmu_rd(ctx, cmu_type, reg, &val); val &= ~bits; cmu_wr(ctx, cmu_type, reg, val); } static void cmu_setbits(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, u32 reg, u32 bits) { u32 val; cmu_rd(ctx, cmu_type, reg, &val); val |= bits; cmu_wr(ctx, cmu_type, reg, val); } static void serdes_wr(struct xgene_phy_ctx *ctx, int lane, u32 reg, u32 data) { void __iomem *sds_base = ctx->sds_base; u32 val; reg += SERDES_INDIRECT_OFFSET; reg += lane * SERDES_LANE_STRIDE; sds_wr(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_WDATA_REG, reg, data); sds_rd(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_RDATA_REG, reg, &val); pr_debug("SERDES WR addr 0x%X value 0x%08X <-> 0x%08X\n", reg, data, val); } static void serdes_rd(struct xgene_phy_ctx *ctx, int lane, u32 reg, u32 *data) { void __iomem *sds_base = ctx->sds_base; reg += SERDES_INDIRECT_OFFSET; reg += lane * SERDES_LANE_STRIDE; sds_rd(sds_base, SATA_ENET_SDS_IND_CMD_REG, SATA_ENET_SDS_IND_RDATA_REG, reg, data); pr_debug("SERDES RD addr 0x%X value 0x%08X\n", reg, *data); } static void serdes_clrbits(struct xgene_phy_ctx *ctx, int lane, u32 reg, u32 bits) { u32 val; serdes_rd(ctx, lane, reg, &val); val &= ~bits; serdes_wr(ctx, lane, reg, val); } static void serdes_setbits(struct xgene_phy_ctx *ctx, int lane, u32 reg, u32 bits) { u32 val; serdes_rd(ctx, lane, reg, &val); val |= bits; serdes_wr(ctx, lane, reg, val); } static void xgene_phy_cfg_cmu_clk_type(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, enum clk_type_t clk_type) { u32 val; /* Set the reset sequence delay for TX ready assertion */ cmu_rd(ctx, cmu_type, CMU_REG12, &val); val = CMU_REG12_STATE_DELAY9_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG12, val); /* Set the programmable stage delays between various enable stages */ cmu_wr(ctx, cmu_type, CMU_REG13, 0x0222); cmu_wr(ctx, cmu_type, CMU_REG14, 0x2225); /* Configure clock type */ if (clk_type == CLK_EXT_DIFF) { /* Select external clock mux */ cmu_rd(ctx, cmu_type, CMU_REG0, &val); val = CMU_REG0_PLL_REF_SEL_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG0, val); /* Select CMOS as reference clock */ cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_REFCLK_CMOS_SEL_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG1, val); dev_dbg(ctx->dev, "Set external reference clock\n"); } else if (clk_type == CLK_INT_DIFF) { /* Select internal clock mux */ cmu_rd(ctx, cmu_type, CMU_REG0, &val); val = CMU_REG0_PLL_REF_SEL_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG0, val); /* Select CMOS as reference clock */ cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_REFCLK_CMOS_SEL_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG1, val); dev_dbg(ctx->dev, "Set internal reference clock\n"); } else if (clk_type == CLK_INT_SING) { /* * NOTE: This clock type is NOT support for controller * whose internal clock shared in the PCIe controller * * Select internal clock mux */ cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_REFCLK_CMOS_SEL_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG1, val); /* Select CML as reference clock */ cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_REFCLK_CMOS_SEL_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG1, val); dev_dbg(ctx->dev, "Set internal single ended reference clock\n"); } } static void xgene_phy_sata_cfg_cmu_core(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, enum clk_type_t clk_type) { u32 val; int ref_100MHz; if (cmu_type == REF_CMU) { /* Set VCO calibration voltage threshold */ cmu_rd(ctx, cmu_type, CMU_REG34, &val); val = CMU_REG34_VCO_CAL_VTH_LO_MAX_SET(val, 0x7); val = CMU_REG34_VCO_CAL_VTH_HI_MAX_SET(val, 0xc); val = CMU_REG34_VCO_CAL_VTH_LO_MIN_SET(val, 0x3); val = CMU_REG34_VCO_CAL_VTH_HI_MIN_SET(val, 0x8); cmu_wr(ctx, cmu_type, CMU_REG34, val); } /* Set the VCO calibration counter */ cmu_rd(ctx, cmu_type, CMU_REG0, &val); if (cmu_type == REF_CMU || preA3Chip) val = CMU_REG0_CAL_COUNT_RESOL_SET(val, 0x4); else val = CMU_REG0_CAL_COUNT_RESOL_SET(val, 0x7); cmu_wr(ctx, cmu_type, CMU_REG0, val); /* Configure PLL for calibration */ cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_PLL_CP_SET(val, 0x1); if (cmu_type == REF_CMU || preA3Chip) val = CMU_REG1_PLL_CP_SEL_SET(val, 0x5); else val = CMU_REG1_PLL_CP_SEL_SET(val, 0x3); if (cmu_type == REF_CMU) val = CMU_REG1_PLL_MANUALCAL_SET(val, 0x0); else val = CMU_REG1_PLL_MANUALCAL_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG1, val); if (cmu_type != REF_CMU) cmu_clrbits(ctx, cmu_type, CMU_REG5, CMU_REG5_PLL_RESETB_MASK); /* Configure the PLL for either 100MHz or 50MHz */ cmu_rd(ctx, cmu_type, CMU_REG2, &val); if (cmu_type == REF_CMU) { val = CMU_REG2_PLL_LFRES_SET(val, 0xa); ref_100MHz = 1; } else { val = CMU_REG2_PLL_LFRES_SET(val, 0x3); if (clk_type == CLK_EXT_DIFF) ref_100MHz = 0; else ref_100MHz = 1; } if (ref_100MHz) { val = CMU_REG2_PLL_FBDIV_SET(val, FBDIV_VAL_100M); val = CMU_REG2_PLL_REFDIV_SET(val, REFDIV_VAL_100M); } else { val = CMU_REG2_PLL_FBDIV_SET(val, FBDIV_VAL_50M); val = CMU_REG2_PLL_REFDIV_SET(val, REFDIV_VAL_50M); } cmu_wr(ctx, cmu_type, CMU_REG2, val); /* Configure the VCO */ cmu_rd(ctx, cmu_type, CMU_REG3, &val); if (cmu_type == REF_CMU) { val = CMU_REG3_VCOVARSEL_SET(val, 0x3); val = CMU_REG3_VCO_MOMSEL_INIT_SET(val, 0x10); } else { val = CMU_REG3_VCOVARSEL_SET(val, 0xF); if (preA3Chip) val = CMU_REG3_VCO_MOMSEL_INIT_SET(val, 0x15); else val = CMU_REG3_VCO_MOMSEL_INIT_SET(val, 0x1a); val = CMU_REG3_VCO_MANMOMSEL_SET(val, 0x15); } cmu_wr(ctx, cmu_type, CMU_REG3, val); /* Disable force PLL lock */ cmu_rd(ctx, cmu_type, CMU_REG26, &val); val = CMU_REG26_FORCE_PLL_LOCK_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG26, val); /* Setup PLL loop filter */ cmu_rd(ctx, cmu_type, CMU_REG5, &val); val = CMU_REG5_PLL_LFSMCAP_SET(val, 0x3); val = CMU_REG5_PLL_LFCAP_SET(val, 0x3); if (cmu_type == REF_CMU || !preA3Chip) val = CMU_REG5_PLL_LOCK_RESOLUTION_SET(val, 0x7); else val = CMU_REG5_PLL_LOCK_RESOLUTION_SET(val, 0x4); cmu_wr(ctx, cmu_type, CMU_REG5, val); /* Enable or disable manual calibration */ cmu_rd(ctx, cmu_type, CMU_REG6, &val); val = CMU_REG6_PLL_VREGTRIM_SET(val, preA3Chip ? 0x0 : 0x2); val = CMU_REG6_MAN_PVT_CAL_SET(val, preA3Chip ? 0x1 : 0x0); cmu_wr(ctx, cmu_type, CMU_REG6, val); /* Configure lane for 20-bits */ if (cmu_type == PHY_CMU) { cmu_rd(ctx, cmu_type, CMU_REG9, &val); val = CMU_REG9_TX_WORD_MODE_CH1_SET(val, CMU_REG9_WORD_LEN_20BIT); val = CMU_REG9_TX_WORD_MODE_CH0_SET(val, CMU_REG9_WORD_LEN_20BIT); val = CMU_REG9_PLL_POST_DIVBY2_SET(val, 0x1); if (!preA3Chip) { val = CMU_REG9_VBG_BYPASSB_SET(val, 0x0); val = CMU_REG9_IGEN_BYPASS_SET(val , 0x0); } cmu_wr(ctx, cmu_type, CMU_REG9, val); if (!preA3Chip) { cmu_rd(ctx, cmu_type, CMU_REG10, &val); val = CMU_REG10_VREG_REFSEL_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG10, val); } } cmu_rd(ctx, cmu_type, CMU_REG16, &val); val = CMU_REG16_CALIBRATION_DONE_OVERRIDE_SET(val, 0x1); val = CMU_REG16_BYPASS_PLL_LOCK_SET(val, 0x1); if (cmu_type == REF_CMU || preA3Chip) val = CMU_REG16_VCOCAL_WAIT_BTW_CODE_SET(val, 0x4); else val = CMU_REG16_VCOCAL_WAIT_BTW_CODE_SET(val, 0x7); cmu_wr(ctx, cmu_type, CMU_REG16, val); /* Configure for SATA */ cmu_rd(ctx, cmu_type, CMU_REG30, &val); val = CMU_REG30_PCIE_MODE_SET(val, 0x0); val = CMU_REG30_LOCK_COUNT_SET(val, 0x3); cmu_wr(ctx, cmu_type, CMU_REG30, val); /* Disable state machine bypass */ cmu_wr(ctx, cmu_type, CMU_REG31, 0xF); cmu_rd(ctx, cmu_type, CMU_REG32, &val); val = CMU_REG32_PVT_CAL_WAIT_SEL_SET(val, 0x3); if (cmu_type == REF_CMU || preA3Chip) val = CMU_REG32_IREF_ADJ_SET(val, 0x3); else val = CMU_REG32_IREF_ADJ_SET(val, 0x1); cmu_wr(ctx, cmu_type, CMU_REG32, val); /* Set VCO calibration threshold */ if (cmu_type != REF_CMU && preA3Chip) cmu_wr(ctx, cmu_type, CMU_REG34, 0x8d27); else cmu_wr(ctx, cmu_type, CMU_REG34, 0x873c); /* Set CTLE Override and override waiting from state machine */ cmu_wr(ctx, cmu_type, CMU_REG37, 0xF00F); } static void xgene_phy_ssc_enable(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type) { u32 val; /* Set SSC modulation value */ cmu_rd(ctx, cmu_type, CMU_REG35, &val); val = CMU_REG35_PLL_SSC_MOD_SET(val, 98); cmu_wr(ctx, cmu_type, CMU_REG35, val); /* Enable SSC, set vertical step and DSM value */ cmu_rd(ctx, cmu_type, CMU_REG36, &val); val = CMU_REG36_PLL_SSC_VSTEP_SET(val, 30); val = CMU_REG36_PLL_SSC_EN_SET(val, 1); val = CMU_REG36_PLL_SSC_DSMSEL_SET(val, 1); cmu_wr(ctx, cmu_type, CMU_REG36, val); /* Reset the PLL */ cmu_clrbits(ctx, cmu_type, CMU_REG5, CMU_REG5_PLL_RESETB_MASK); cmu_setbits(ctx, cmu_type, CMU_REG5, CMU_REG5_PLL_RESETB_MASK); /* Force VCO calibration to restart */ cmu_toggle1to0(ctx, cmu_type, CMU_REG32, CMU_REG32_FORCE_VCOCAL_START_MASK); } static void xgene_phy_sata_cfg_lanes(struct xgene_phy_ctx *ctx) { u32 val; u32 reg; int i; int lane; for (lane = 0; lane < MAX_LANE; lane++) { serdes_wr(ctx, lane, RXTX_REG147, 0x6); /* Set boost control for quarter, half, and full rate */ serdes_rd(ctx, lane, RXTX_REG0, &val); val = RXTX_REG0_CTLE_EQ_HR_SET(val, 0x10); val = RXTX_REG0_CTLE_EQ_QR_SET(val, 0x10); val = RXTX_REG0_CTLE_EQ_FR_SET(val, 0x10); serdes_wr(ctx, lane, RXTX_REG0, val); /* Set boost control value */ serdes_rd(ctx, lane, RXTX_REG1, &val); val = RXTX_REG1_RXACVCM_SET(val, 0x7); val = RXTX_REG1_CTLE_EQ_SET(val, ctx->sata_param.txboostgain[lane * 3 + ctx->sata_param.speed[lane]]); serdes_wr(ctx, lane, RXTX_REG1, val); /* Latch VTT value based on the termination to ground and enable TX FIFO */ serdes_rd(ctx, lane, RXTX_REG2, &val); val = RXTX_REG2_VTT_ENA_SET(val, 0x1); val = RXTX_REG2_VTT_SEL_SET(val, 0x1); val = RXTX_REG2_TX_FIFO_ENA_SET(val, 0x1); serdes_wr(ctx, lane, RXTX_REG2, val); /* Configure Tx for 20-bits */ serdes_rd(ctx, lane, RXTX_REG4, &val); val = RXTX_REG4_TX_WORD_MODE_SET(val, CMU_REG9_WORD_LEN_20BIT); serdes_wr(ctx, lane, RXTX_REG4, val); if (!preA3Chip) { serdes_rd(ctx, lane, RXTX_REG1, &val); val = RXTX_REG1_RXVREG1_SET(val, 0x2); val = RXTX_REG1_RXIREF_ADJ_SET(val, 0x2); serdes_wr(ctx, lane, RXTX_REG1, val); } /* Set pre-emphasis first 1 and 2, and post-emphasis values */ serdes_rd(ctx, lane, RXTX_REG5, &val); val = RXTX_REG5_TX_CN1_SET(val, ctx->sata_param.txprecursor_cn1[lane * 3 + ctx->sata_param.speed[lane]]); val = RXTX_REG5_TX_CP1_SET(val, ctx->sata_param.txpostcursor_cp1[lane * 3 + ctx->sata_param.speed[lane]]); val = RXTX_REG5_TX_CN2_SET(val, ctx->sata_param.txprecursor_cn2[lane * 3 + ctx->sata_param.speed[lane]]); serdes_wr(ctx, lane, RXTX_REG5, val); /* Set TX amplitude value */ serdes_rd(ctx, lane, RXTX_REG6, &val); val = RXTX_REG6_TXAMP_CNTL_SET(val, ctx->sata_param.txamplitude[lane * 3 + ctx->sata_param.speed[lane]]); val = RXTX_REG6_TXAMP_ENA_SET(val, 0x1); val = RXTX_REG6_TX_IDLE_SET(val, 0x0); val = RXTX_REG6_RX_BIST_RESYNC_SET(val, 0x0); val = RXTX_REG6_RX_BIST_ERRCNT_RD_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG6, val); /* Configure Rx for 20-bits */ serdes_rd(ctx, lane, RXTX_REG7, &val); val = RXTX_REG7_BIST_ENA_RX_SET(val, 0x0); val = RXTX_REG7_RX_WORD_MODE_SET(val, CMU_REG9_WORD_LEN_20BIT); serdes_wr(ctx, lane, RXTX_REG7, val); /* Set CDR and LOS values and enable Rx SSC */ serdes_rd(ctx, lane, RXTX_REG8, &val); val = RXTX_REG8_CDR_LOOP_ENA_SET(val, 0x1); val = RXTX_REG8_CDR_BYPASS_RXLOS_SET(val, 0x0); val = RXTX_REG8_SSC_ENABLE_SET(val, 0x1); val = RXTX_REG8_SD_DISABLE_SET(val, 0x0); val = RXTX_REG8_SD_VREF_SET(val, 0x4); serdes_wr(ctx, lane, RXTX_REG8, val); /* Set phase adjust upper/lower limits */ serdes_rd(ctx, lane, RXTX_REG11, &val); val = RXTX_REG11_PHASE_ADJUST_LIMIT_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG11, val); /* Enable Latch Off; disable SUMOS and Tx termination */ serdes_rd(ctx, lane, RXTX_REG12, &val); val = RXTX_REG12_LATCH_OFF_ENA_SET(val, 0x1); val = RXTX_REG12_SUMOS_ENABLE_SET(val, 0x0); val = RXTX_REG12_RX_DET_TERM_ENABLE_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG12, val); /* Set period error latch to 512T and enable BWL */ serdes_rd(ctx, lane, RXTX_REG26, &val); val = RXTX_REG26_PERIOD_ERROR_LATCH_SET(val, 0x0); val = RXTX_REG26_BLWC_ENA_SET(val, 0x1); serdes_wr(ctx, lane, RXTX_REG26, val); serdes_wr(ctx, lane, RXTX_REG28, 0x0); /* Set DFE loop preset value */ serdes_wr(ctx, lane, RXTX_REG31, 0x0); /* Set Eye Monitor counter width to 12-bit */ serdes_rd(ctx, lane, RXTX_REG61, &val); val = RXTX_REG61_ISCAN_INBERT_SET(val, 0x1); val = RXTX_REG61_LOADFREQ_SHIFT_SET(val, 0x0); val = RXTX_REG61_EYE_COUNT_WIDTH_SEL_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG61, val); serdes_rd(ctx, lane, RXTX_REG62, &val); val = RXTX_REG62_PERIOD_H1_QLATCH_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG62, val); /* Set BW select tap X for DFE loop */ for (i = 0; i < 9; i++) { reg = RXTX_REG81 + i * 2; serdes_rd(ctx, lane, reg, &val); val = RXTX_REG89_MU_TH7_SET(val, 0xe); val = RXTX_REG89_MU_TH8_SET(val, 0xe); val = RXTX_REG89_MU_TH9_SET(val, 0xe); serdes_wr(ctx, lane, reg, val); } /* Set BW select tap X for frequency adjust loop */ for (i = 0; i < 3; i++) { reg = RXTX_REG96 + i * 2; serdes_rd(ctx, lane, reg, &val); val = RXTX_REG96_MU_FREQ1_SET(val, 0x10); val = RXTX_REG96_MU_FREQ2_SET(val, 0x10); val = RXTX_REG96_MU_FREQ3_SET(val, 0x10); serdes_wr(ctx, lane, reg, val); } /* Set BW select tap X for phase adjust loop */ for (i = 0; i < 3; i++) { reg = RXTX_REG99 + i * 2; serdes_rd(ctx, lane, reg, &val); val = RXTX_REG99_MU_PHASE1_SET(val, 0x7); val = RXTX_REG99_MU_PHASE2_SET(val, 0x7); val = RXTX_REG99_MU_PHASE3_SET(val, 0x7); serdes_wr(ctx, lane, reg, val); } serdes_rd(ctx, lane, RXTX_REG102, &val); val = RXTX_REG102_FREQLOOP_LIMIT_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG102, val); serdes_wr(ctx, lane, RXTX_REG114, 0xffe0); serdes_rd(ctx, lane, RXTX_REG125, &val); val = RXTX_REG125_SIGN_PQ_SET(val, ctx->sata_param.txeyedirection[lane * 3 + ctx->sata_param.speed[lane]]); val = RXTX_REG125_PQ_REG_SET(val, ctx->sata_param.txeyetuning[lane * 3 + ctx->sata_param.speed[lane]]); val = RXTX_REG125_PHZ_MANUAL_SET(val, 0x1); serdes_wr(ctx, lane, RXTX_REG125, val); serdes_rd(ctx, lane, RXTX_REG127, &val); val = RXTX_REG127_LATCH_MAN_CAL_ENA_SET(val, 0x0); serdes_wr(ctx, lane, RXTX_REG127, val); serdes_rd(ctx, lane, RXTX_REG128, &val); val = RXTX_REG128_LATCH_CAL_WAIT_SEL_SET(val, 0x3); serdes_wr(ctx, lane, RXTX_REG128, val); serdes_rd(ctx, lane, RXTX_REG145, &val); val = RXTX_REG145_RXDFE_CONFIG_SET(val, 0x3); val = RXTX_REG145_TX_IDLE_SATA_SET(val, 0x0); if (preA3Chip) { val = RXTX_REG145_RXES_ENA_SET(val, 0x1); val = RXTX_REG145_RXVWES_LATENA_SET(val, 0x1); } else { val = RXTX_REG145_RXES_ENA_SET(val, 0x0); val = RXTX_REG145_RXVWES_LATENA_SET(val, 0x0); } serdes_wr(ctx, lane, RXTX_REG145, val); /* * Set Rx LOS filter clock rate, sample rate, and threshold * windows */ for (i = 0; i < 4; i++) { reg = RXTX_REG148 + i * 2; serdes_wr(ctx, lane, reg, 0xFFFF); } } } static int xgene_phy_cal_rdy_chk(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, enum clk_type_t clk_type) { void __iomem *csr_serdes = ctx->sds_base; int loop; u32 val; /* Release PHY main reset */ writel(0xdf, csr_serdes + SATA_ENET_SDS_RST_CTL); readl(csr_serdes + SATA_ENET_SDS_RST_CTL); /* Force a barrier */ if (cmu_type != REF_CMU) { cmu_setbits(ctx, cmu_type, CMU_REG5, CMU_REG5_PLL_RESETB_MASK); /* * As per PHY design spec, the PLL reset requires a minimum * of 800us. */ usleep_range(800, 1000); cmu_rd(ctx, cmu_type, CMU_REG1, &val); val = CMU_REG1_PLL_MANUALCAL_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG1, val); /* * As per PHY design spec, the PLL auto calibration requires * a minimum of 800us. */ usleep_range(800, 1000); cmu_toggle1to0(ctx, cmu_type, CMU_REG32, CMU_REG32_FORCE_VCOCAL_START_MASK); /* * As per PHY design spec, the PLL requires a minimum of * 800us to settle. */ usleep_range(800, 1000); } if (!preA3Chip) goto skip_manual_cal; /* * Configure the termination resister calibration * The serial receive pins, RXP/RXN, have TERMination resistor * that is required to be calibrated. */ cmu_rd(ctx, cmu_type, CMU_REG17, &val); val = CMU_REG17_PVT_CODE_R2A_SET(val, 0x12); val = CMU_REG17_RESERVED_7_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG17, val); cmu_toggle1to0(ctx, cmu_type, CMU_REG17, CMU_REG17_PVT_TERM_MAN_ENA_MASK); /* * The serial transmit pins, TXP/TXN, have Pull-UP and Pull-DOWN * resistors that are required to the calibrated. * Configure the pull DOWN calibration */ cmu_rd(ctx, cmu_type, CMU_REG17, &val); val = CMU_REG17_PVT_CODE_R2A_SET(val, 0x29); val = CMU_REG17_RESERVED_7_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG17, val); cmu_toggle1to0(ctx, cmu_type, CMU_REG16, CMU_REG16_PVT_DN_MAN_ENA_MASK); /* Configure the pull UP calibration */ cmu_rd(ctx, cmu_type, CMU_REG17, &val); val = CMU_REG17_PVT_CODE_R2A_SET(val, 0x28); val = CMU_REG17_RESERVED_7_SET(val, 0x0); cmu_wr(ctx, cmu_type, CMU_REG17, val); cmu_toggle1to0(ctx, cmu_type, CMU_REG16, CMU_REG16_PVT_UP_MAN_ENA_MASK); skip_manual_cal: /* Poll the PLL calibration completion status for at least 1 ms */ loop = 100; do { cmu_rd(ctx, cmu_type, CMU_REG7, &val); if (CMU_REG7_PLL_CALIB_DONE_RD(val)) break; /* * As per PHY design spec, PLL calibration status requires * a minimum of 10us to be updated. */ usleep_range(10, 100); } while (--loop > 0); cmu_rd(ctx, cmu_type, CMU_REG7, &val); dev_dbg(ctx->dev, "PLL calibration %s\n", CMU_REG7_PLL_CALIB_DONE_RD(val) ? "done" : "failed"); if (CMU_REG7_VCO_CAL_FAIL_RD(val)) { dev_err(ctx->dev, "PLL calibration failed due to VCO failure\n"); return -1; } dev_dbg(ctx->dev, "PLL calibration successful\n"); cmu_rd(ctx, cmu_type, CMU_REG15, &val); dev_dbg(ctx->dev, "PHY Tx is %sready\n", val & 0x300 ? "" : "not "); return 0; } static void xgene_phy_pdwn_force_vco(struct xgene_phy_ctx *ctx, enum cmu_type_t cmu_type, enum clk_type_t clk_type) { u32 val; dev_dbg(ctx->dev, "Reset VCO and re-start again\n"); if (cmu_type == PHY_CMU) { cmu_rd(ctx, cmu_type, CMU_REG16, &val); val = CMU_REG16_VCOCAL_WAIT_BTW_CODE_SET(val, 0x7); cmu_wr(ctx, cmu_type, CMU_REG16, val); } cmu_toggle1to0(ctx, cmu_type, CMU_REG0, CMU_REG0_PDOWN_MASK); cmu_toggle1to0(ctx, cmu_type, CMU_REG32, CMU_REG32_FORCE_VCOCAL_START_MASK); } static int xgene_phy_hw_init_sata(struct xgene_phy_ctx *ctx, enum clk_type_t clk_type, int ssc_enable) { void __iomem *sds_base = ctx->sds_base; u32 val; int i; /* Configure the PHY for operation */ dev_dbg(ctx->dev, "Reset PHY\n"); /* Place PHY into reset */ writel(0x0, sds_base + SATA_ENET_SDS_RST_CTL); val = readl(sds_base + SATA_ENET_SDS_RST_CTL); /* Force a barrier */ /* Release PHY lane from reset (active high) */ writel(0x20, sds_base + SATA_ENET_SDS_RST_CTL); readl(sds_base + SATA_ENET_SDS_RST_CTL); /* Force a barrier */ /* Release all PHY module out of reset except PHY main reset */ writel(0xde, sds_base + SATA_ENET_SDS_RST_CTL); readl(sds_base + SATA_ENET_SDS_RST_CTL); /* Force a barrier */ /* Set the operation speed */ val = readl(sds_base + SATA_ENET_SDS_CTL1); val = CFG_I_SPD_SEL_CDR_OVR1_SET(val, ctx->sata_param.txspeed[ctx->sata_param.speed[0]]); writel(val, sds_base + SATA_ENET_SDS_CTL1); dev_dbg(ctx->dev, "Set the customer pin mode to SATA\n"); val = readl(sds_base + SATA_ENET_SDS_CTL0); val = REGSPEC_CFG_I_CUSTOMER_PIN_MODE0_SET(val, 0x4421); writel(val, sds_base + SATA_ENET_SDS_CTL0); /* Configure the clock macro unit (CMU) clock type */ xgene_phy_cfg_cmu_clk_type(ctx, PHY_CMU, clk_type); /* Configure the clock macro */ xgene_phy_sata_cfg_cmu_core(ctx, PHY_CMU, clk_type); /* Enable SSC if enabled */ if (ssc_enable) xgene_phy_ssc_enable(ctx, PHY_CMU); /* Configure PHY lanes */ xgene_phy_sata_cfg_lanes(ctx); /* Set Rx/Tx 20-bit */ val = readl(sds_base + SATA_ENET_SDS_PCS_CTL0); val = REGSPEC_CFG_I_RX_WORDMODE0_SET(val, 0x3); val = REGSPEC_CFG_I_TX_WORDMODE0_SET(val, 0x3); writel(val, sds_base + SATA_ENET_SDS_PCS_CTL0); /* Start PLL calibration and try for three times */ i = 10; do { if (!xgene_phy_cal_rdy_chk(ctx, PHY_CMU, clk_type)) break; /* If failed, toggle the VCO power signal and start again */ xgene_phy_pdwn_force_vco(ctx, PHY_CMU, clk_type); } while (--i > 0); /* Even on failure, allow to continue any way */ if (i <= 0) dev_err(ctx->dev, "PLL calibration failed\n"); return 0; } static int xgene_phy_hw_initialize(struct xgene_phy_ctx *ctx, enum clk_type_t clk_type, int ssc_enable) { int rc; dev_dbg(ctx->dev, "PHY init clk type %d\n", clk_type); if (ctx->mode == MODE_SATA) { rc = xgene_phy_hw_init_sata(ctx, clk_type, ssc_enable); if (rc) return rc; } else { dev_err(ctx->dev, "Un-supported customer pin mode %d\n", ctx->mode); return -ENODEV; } return 0; } /* * Receiver Offset Calibration: * * Calibrate the receiver signal path offset in two steps - summar and * latch calibrations */ static void xgene_phy_force_lat_summer_cal(struct xgene_phy_ctx *ctx, int lane) { int i; static const struct { u32 reg; u32 val; } serdes_reg[] = { {RXTX_REG38, 0x0}, {RXTX_REG39, 0xff00}, {RXTX_REG40, 0xffff}, {RXTX_REG41, 0xffff}, {RXTX_REG42, 0xffff}, {RXTX_REG43, 0xffff}, {RXTX_REG44, 0xffff}, {RXTX_REG45, 0xffff}, {RXTX_REG46, 0xffff}, {RXTX_REG47, 0xfffc}, {RXTX_REG48, 0x0}, {RXTX_REG49, 0x0}, {RXTX_REG50, 0x0}, {RXTX_REG51, 0x0}, {RXTX_REG52, 0x0}, {RXTX_REG53, 0x0}, {RXTX_REG54, 0x0}, {RXTX_REG55, 0x0}, }; /* Start SUMMER calibration */ serdes_setbits(ctx, lane, RXTX_REG127, RXTX_REG127_FORCE_SUM_CAL_START_MASK); /* * As per PHY design spec, the Summer calibration requires a minimum * of 100us to complete. */ usleep_range(100, 500); serdes_clrbits(ctx, lane, RXTX_REG127, RXTX_REG127_FORCE_SUM_CAL_START_MASK); /* * As per PHY design spec, the auto calibration requires a minimum * of 100us to complete. */ usleep_range(100, 500); /* Start latch calibration */ serdes_setbits(ctx, lane, RXTX_REG127, RXTX_REG127_FORCE_LAT_CAL_START_MASK); /* * As per PHY design spec, the latch calibration requires a minimum * of 100us to complete. */ usleep_range(100, 500); serdes_clrbits(ctx, lane, RXTX_REG127, RXTX_REG127_FORCE_LAT_CAL_START_MASK); /* Configure the PHY lane for calibration */ serdes_wr(ctx, lane, RXTX_REG28, 0x7); serdes_wr(ctx, lane, RXTX_REG31, 0x7e00); serdes_clrbits(ctx, lane, RXTX_REG4, RXTX_REG4_TX_LOOPBACK_BUF_EN_MASK); serdes_clrbits(ctx, lane, RXTX_REG7, RXTX_REG7_LOOP_BACK_ENA_CTLE_MASK); for (i = 0; i < ARRAY_SIZE(serdes_reg); i++) serdes_wr(ctx, lane, serdes_reg[i].reg, serdes_reg[i].val); } static void xgene_phy_reset_rxd(struct xgene_phy_ctx *ctx, int lane) { /* Reset digital Rx */ serdes_clrbits(ctx, lane, RXTX_REG7, RXTX_REG7_RESETB_RXD_MASK); /* As per PHY design spec, the reset requires a minimum of 100us. */ usleep_range(100, 150); serdes_setbits(ctx, lane, RXTX_REG7, RXTX_REG7_RESETB_RXD_MASK); } static int xgene_phy_get_avg(int accum, int samples) { return (accum + (samples / 2)) / samples; } static void xgene_phy_gen_avg_val(struct xgene_phy_ctx *ctx, int lane) { int max_loop = 10; int avg_loop = 0; int lat_do = 0, lat_xo = 0, lat_eo = 0, lat_so = 0; int lat_de = 0, lat_xe = 0, lat_ee = 0, lat_se = 0; int sum_cal = 0; int lat_do_itr, lat_xo_itr, lat_eo_itr, lat_so_itr; int lat_de_itr, lat_xe_itr, lat_ee_itr, lat_se_itr; int sum_cal_itr; int fail_even; int fail_odd; u32 val; dev_dbg(ctx->dev, "Generating avg calibration value for lane %d\n", lane); /* Enable RX Hi-Z termination */ serdes_setbits(ctx, lane, RXTX_REG12, RXTX_REG12_RX_DET_TERM_ENABLE_MASK); /* Turn off DFE */ serdes_wr(ctx, lane, RXTX_REG28, 0x0000); /* DFE Presets to zero */ serdes_wr(ctx, lane, RXTX_REG31, 0x0000); /* * Receiver Offset Calibration: * Calibrate the receiver signal path offset in two steps - summar * and latch calibration. * Runs the "Receiver Offset Calibration multiple times to determine * the average value to use. */ while (avg_loop < max_loop) { /* Start the calibration */ xgene_phy_force_lat_summer_cal(ctx, lane); serdes_rd(ctx, lane, RXTX_REG21, &val); lat_do_itr = RXTX_REG21_DO_LATCH_CALOUT_RD(val); lat_xo_itr = RXTX_REG21_XO_LATCH_CALOUT_RD(val); fail_odd = RXTX_REG21_LATCH_CAL_FAIL_ODD_RD(val); serdes_rd(ctx, lane, RXTX_REG22, &val); lat_eo_itr = RXTX_REG22_EO_LATCH_CALOUT_RD(val); lat_so_itr = RXTX_REG22_SO_LATCH_CALOUT_RD(val); fail_even = RXTX_REG22_LATCH_CAL_FAIL_EVEN_RD(val); serdes_rd(ctx, lane, RXTX_REG23, &val); lat_de_itr = RXTX_REG23_DE_LATCH_CALOUT_RD(val); lat_xe_itr = RXTX_REG23_XE_LATCH_CALOUT_RD(val); serdes_rd(ctx, lane, RXTX_REG24, &val); lat_ee_itr = RXTX_REG24_EE_LATCH_CALOUT_RD(val); lat_se_itr = RXTX_REG24_SE_LATCH_CALOUT_RD(val); serdes_rd(ctx, lane, RXTX_REG121, &val); sum_cal_itr = RXTX_REG121_SUMOS_CAL_CODE_RD(val); /* Check for failure. If passed, sum them for averaging */ if ((fail_even == 0 || fail_even == 1) && (fail_odd == 0 || fail_odd == 1)) { lat_do += lat_do_itr; lat_xo += lat_xo_itr; lat_eo += lat_eo_itr; lat_so += lat_so_itr; lat_de += lat_de_itr; lat_xe += lat_xe_itr; lat_ee += lat_ee_itr; lat_se += lat_se_itr; sum_cal += sum_cal_itr; dev_dbg(ctx->dev, "Iteration %d:\n", avg_loop); dev_dbg(ctx->dev, "DO 0x%x XO 0x%x EO 0x%x SO 0x%x\n", lat_do_itr, lat_xo_itr, lat_eo_itr, lat_so_itr); dev_dbg(ctx->dev, "DE 0x%x XE 0x%x EE 0x%x SE 0x%x\n", lat_de_itr, lat_xe_itr, lat_ee_itr, lat_se_itr); dev_dbg(ctx->dev, "SUM 0x%x\n", sum_cal_itr); ++avg_loop; } else { dev_err(ctx->dev, "Receiver calibration failed at %d loop\n", avg_loop); } xgene_phy_reset_rxd(ctx, lane); } /* Update latch manual calibration with average value */ serdes_rd(ctx, lane, RXTX_REG127, &val); val = RXTX_REG127_DO_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_do, max_loop)); val = RXTX_REG127_XO_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_xo, max_loop)); serdes_wr(ctx, lane, RXTX_REG127, val); serdes_rd(ctx, lane, RXTX_REG128, &val); val = RXTX_REG128_EO_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_eo, max_loop)); val = RXTX_REG128_SO_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_so, max_loop)); serdes_wr(ctx, lane, RXTX_REG128, val); serdes_rd(ctx, lane, RXTX_REG129, &val); val = RXTX_REG129_DE_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_de, max_loop)); val = RXTX_REG129_XE_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_xe, max_loop)); serdes_wr(ctx, lane, RXTX_REG129, val); serdes_rd(ctx, lane, RXTX_REG130, &val); val = RXTX_REG130_EE_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_ee, max_loop)); val = RXTX_REG130_SE_LATCH_MANCAL_SET(val, xgene_phy_get_avg(lat_se, max_loop)); serdes_wr(ctx, lane, RXTX_REG130, val); /* Update SUMMER calibration with average value */ serdes_rd(ctx, lane, RXTX_REG14, &val); val = RXTX_REG14_CLTE_LATCAL_MAN_PROG_SET(val, xgene_phy_get_avg(sum_cal, max_loop)); serdes_wr(ctx, lane, RXTX_REG14, val); dev_dbg(ctx->dev, "Average Value:\n"); dev_dbg(ctx->dev, "DO 0x%x XO 0x%x EO 0x%x SO 0x%x\n", xgene_phy_get_avg(lat_do, max_loop), xgene_phy_get_avg(lat_xo, max_loop), xgene_phy_get_avg(lat_eo, max_loop), xgene_phy_get_avg(lat_so, max_loop)); dev_dbg(ctx->dev, "DE 0x%x XE 0x%x EE 0x%x SE 0x%x\n", xgene_phy_get_avg(lat_de, max_loop), xgene_phy_get_avg(lat_xe, max_loop), xgene_phy_get_avg(lat_ee, max_loop), xgene_phy_get_avg(lat_se, max_loop)); dev_dbg(ctx->dev, "SUM 0x%x\n", xgene_phy_get_avg(sum_cal, max_loop)); serdes_rd(ctx, lane, RXTX_REG14, &val); val = RXTX_REG14_CTLE_LATCAL_MAN_ENA_SET(val, 0x1); serdes_wr(ctx, lane, RXTX_REG14, val); dev_dbg(ctx->dev, "Enable Manual Summer calibration\n"); serdes_rd(ctx, lane, RXTX_REG127, &val); val = RXTX_REG127_LATCH_MAN_CAL_ENA_SET(val, 0x1); dev_dbg(ctx->dev, "Enable Manual Latch calibration\n"); serdes_wr(ctx, lane, RXTX_REG127, val); /* Disable RX Hi-Z termination */ serdes_rd(ctx, lane, RXTX_REG12, &val); val = RXTX_REG12_RX_DET_TERM_ENABLE_SET(val, 0); serdes_wr(ctx, lane, RXTX_REG12, val); /* Turn on DFE */ serdes_wr(ctx, lane, RXTX_REG28, 0x0007); /* Set DFE preset */ serdes_wr(ctx, lane, RXTX_REG31, 0x7e00); } static int xgene_phy_hw_init(struct phy *phy) { struct xgene_phy_ctx *ctx = phy_get_drvdata(phy); int rc; int i; rc = xgene_phy_hw_initialize(ctx, CLK_EXT_DIFF, SSC_DISABLE); if (rc) { dev_err(ctx->dev, "PHY initialize failed %d\n", rc); return rc; } /* Setup clock properly after PHY configuration */ if (!IS_ERR(ctx->clk)) { /* HW requires an toggle of the clock */ clk_prepare_enable(ctx->clk); clk_disable_unprepare(ctx->clk); clk_prepare_enable(ctx->clk); } /* Compute average value */ for (i = 0; i < MAX_LANE; i++) xgene_phy_gen_avg_val(ctx, i); dev_dbg(ctx->dev, "PHY initialized\n"); return 0; } static const struct phy_ops xgene_phy_ops = { .init = xgene_phy_hw_init, .owner = THIS_MODULE, }; static struct phy *xgene_phy_xlate(struct device *dev, struct of_phandle_args *args) { struct xgene_phy_ctx *ctx = dev_get_drvdata(dev); if (args->args_count <= 0) return ERR_PTR(-EINVAL); if (args->args[0] < MODE_SATA || args->args[0] >= MODE_MAX) return ERR_PTR(-EINVAL); ctx->mode = args->args[0]; return ctx->phy; } static void xgene_phy_get_param(struct platform_device *pdev, const char *name, u32 *buffer, int count, u32 *default_val, u32 conv_factor) { int i; if (!of_property_read_u32_array(pdev->dev.of_node, name, buffer, count)) { for (i = 0; i < count; i++) buffer[i] /= conv_factor; return; } /* Does not exist, load default */ for (i = 0; i < count; i++) buffer[i] = default_val[i % 3]; } static int xgene_phy_probe(struct platform_device *pdev) { struct phy_provider *phy_provider; struct xgene_phy_ctx *ctx; struct resource *res; u32 default_spd[] = DEFAULT_SATA_SPD_SEL; u32 default_txboost_gain[] = DEFAULT_SATA_TXBOOST_GAIN; u32 default_txeye_direction[] = DEFAULT_SATA_TXEYEDIRECTION; u32 default_txeye_tuning[] = DEFAULT_SATA_TXEYETUNING; u32 default_txamp[] = DEFAULT_SATA_TXAMP; u32 default_txcn1[] = DEFAULT_SATA_TXCN1; u32 default_txcn2[] = DEFAULT_SATA_TXCN2; u32 default_txcp1[] = DEFAULT_SATA_TXCP1; int i; ctx = devm_kzalloc(&pdev->dev, sizeof(*ctx), GFP_KERNEL); if (!ctx) return -ENOMEM; ctx->dev = &pdev->dev; res = platform_get_resource(pdev, IORESOURCE_MEM, 0); ctx->sds_base = devm_ioremap_resource(&pdev->dev, res); if (IS_ERR(ctx->sds_base)) return PTR_ERR(ctx->sds_base); /* Retrieve optional clock */ ctx->clk = clk_get(&pdev->dev, NULL); /* Load override paramaters */ xgene_phy_get_param(pdev, "apm,tx-eye-tuning", ctx->sata_param.txeyetuning, 6, default_txeye_tuning, 1); xgene_phy_get_param(pdev, "apm,tx-eye-direction", ctx->sata_param.txeyedirection, 6, default_txeye_direction, 1); xgene_phy_get_param(pdev, "apm,tx-boost-gain", ctx->sata_param.txboostgain, 6, default_txboost_gain, 1); xgene_phy_get_param(pdev, "apm,tx-amplitude", ctx->sata_param.txamplitude, 6, default_txamp, 13300); xgene_phy_get_param(pdev, "apm,tx-pre-cursor1", ctx->sata_param.txprecursor_cn1, 6, default_txcn1, 18200); xgene_phy_get_param(pdev, "apm,tx-pre-cursor2", ctx->sata_param.txprecursor_cn2, 6, default_txcn2, 18200); xgene_phy_get_param(pdev, "apm,tx-post-cursor", ctx->sata_param.txpostcursor_cp1, 6, default_txcp1, 18200); xgene_phy_get_param(pdev, "apm,tx-speed", ctx->sata_param.txspeed, 3, default_spd, 1); for (i = 0; i < MAX_LANE; i++) ctx->sata_param.speed[i] = 2; /* Default to Gen3 */ platform_set_drvdata(pdev, ctx); ctx->phy = devm_phy_create(ctx->dev, NULL, &xgene_phy_ops); if (IS_ERR(ctx->phy)) { dev_dbg(&pdev->dev, "Failed to create PHY\n"); return PTR_ERR(ctx->phy); } phy_set_drvdata(ctx->phy, ctx); phy_provider = devm_of_phy_provider_register(ctx->dev, xgene_phy_xlate); return PTR_ERR_OR_ZERO(phy_provider); } static const struct of_device_id xgene_phy_of_match[] = { {.compatible = "apm,xgene-phy",}, {}, }; MODULE_DEVICE_TABLE(of, xgene_phy_of_match); static struct platform_driver xgene_phy_driver = { .probe = xgene_phy_probe, .driver = { .name = "xgene-phy", .of_match_table = xgene_phy_of_match, }, }; module_platform_driver(xgene_phy_driver); MODULE_DESCRIPTION("APM X-Gene Multi-Purpose PHY driver"); MODULE_AUTHOR("Loc Ho <lho@apm.com>"); MODULE_LICENSE("GPL v2"); MODULE_VERSION("0.1"); |