| // SPDX-License-Identifier: GPL-2.0 |
| /* |
| * Copyright (C) 2020 Marvell International Ltd. |
| */ |
| |
| #include <dm.h> |
| #include <time.h> |
| #include <linux/delay.h> |
| |
| #include <mach/cvmx-regs.h> |
| #include <mach/octeon-model.h> |
| #include <mach/cvmx-fuse.h> |
| #include <mach/cvmx-qlm.h> |
| #include <mach/octeon_qlm.h> |
| #include <mach/cvmx-pcie.h> |
| |
| #include <mach/cvmx-bgxx-defs.h> |
| #include <mach/cvmx-ciu-defs.h> |
| #include <mach/cvmx-gmxx-defs.h> |
| #include <mach/cvmx-gserx-defs.h> |
| #include <mach/cvmx-mio-defs.h> |
| #include <mach/cvmx-pciercx-defs.h> |
| #include <mach/cvmx-pemx-defs.h> |
| #include <mach/cvmx-pexp-defs.h> |
| #include <mach/cvmx-rst-defs.h> |
| #include <mach/cvmx-sata-defs.h> |
| #include <mach/cvmx-sli-defs.h> |
| #include <mach/cvmx-sriomaintx-defs.h> |
| #include <mach/cvmx-sriox-defs.h> |
| |
| DECLARE_GLOBAL_DATA_PTR; |
| |
| /** 2.5GHz with 100MHz reference clock */ |
| #define R_2_5G_REFCLK100 0x0 |
| /** 5.0GHz with 100MHz reference clock */ |
| #define R_5G_REFCLK100 0x1 |
| /** 8.0GHz with 100MHz reference clock */ |
| #define R_8G_REFCLK100 0x2 |
| /** 1.25GHz with 156.25MHz reference clock */ |
| #define R_125G_REFCLK15625_KX 0x3 |
| /** 3.125Ghz with 156.25MHz reference clock (XAUI) */ |
| #define R_3125G_REFCLK15625_XAUI 0x4 |
| /** 10.3125GHz with 156.25MHz reference clock (XFI/XLAUI) */ |
| #define R_103125G_REFCLK15625_KR 0x5 |
| /** 1.25GHz with 156.25MHz reference clock (SGMII) */ |
| #define R_125G_REFCLK15625_SGMII 0x6 |
| /** 5GHz with 156.25MHz reference clock (QSGMII) */ |
| #define R_5G_REFCLK15625_QSGMII 0x7 |
| /** 6.25GHz with 156.25MHz reference clock (RXAUI/25G) */ |
| #define R_625G_REFCLK15625_RXAUI 0x8 |
| /** 2.5GHz with 125MHz reference clock */ |
| #define R_2_5G_REFCLK125 0x9 |
| /** 5GHz with 125MHz reference clock */ |
| #define R_5G_REFCLK125 0xa |
| /** 8GHz with 125MHz reference clock */ |
| #define R_8G_REFCLK125 0xb |
| /** Must be last, number of modes */ |
| #define R_NUM_LANE_MODES 0xc |
| |
| int cvmx_qlm_is_ref_clock(int qlm, int reference_mhz) |
| { |
| int ref_clock = cvmx_qlm_measure_clock(qlm); |
| int mhz = ref_clock / 1000000; |
| int range = reference_mhz / 10; |
| |
| return ((mhz >= reference_mhz - range) && (mhz <= reference_mhz + range)); |
| } |
| |
| static int __get_qlm_spd(int qlm, int speed) |
| { |
| int qlm_spd = 0xf; |
| |
| if (cvmx_qlm_is_ref_clock(qlm, 100)) { |
| if (speed == 1250) |
| qlm_spd = 0x3; |
| else if (speed == 2500) |
| qlm_spd = 0x2; |
| else if (speed == 5000) |
| qlm_spd = 0x0; |
| else |
| qlm_spd = 0xf; |
| } else if (cvmx_qlm_is_ref_clock(qlm, 125)) { |
| if (speed == 1250) |
| qlm_spd = 0xa; |
| else if (speed == 2500) |
| qlm_spd = 0x9; |
| else if (speed == 3125) |
| qlm_spd = 0x8; |
| else if (speed == 5000) |
| qlm_spd = 0x6; |
| else if (speed == 6250) |
| qlm_spd = 0x5; |
| else |
| qlm_spd = 0xf; |
| } else if (cvmx_qlm_is_ref_clock(qlm, 156)) { |
| if (speed == 1250) |
| qlm_spd = 0x4; |
| else if (speed == 2500) |
| qlm_spd = 0x7; |
| else if (speed == 3125) |
| qlm_spd = 0xe; |
| else if (speed == 3750) |
| qlm_spd = 0xd; |
| else if (speed == 5000) |
| qlm_spd = 0xb; |
| else if (speed == 6250) |
| qlm_spd = 0xc; |
| else |
| qlm_spd = 0xf; |
| } else if (cvmx_qlm_is_ref_clock(qlm, 161)) { |
| if (speed == 6316) |
| qlm_spd = 0xc; |
| } |
| return qlm_spd; |
| } |
| |
| static void __set_qlm_pcie_mode_61xx(int pcie_port, int root_complex) |
| { |
| int rc = root_complex ? 1 : 0; |
| int ep = root_complex ? 0 : 1; |
| cvmx_ciu_soft_prst1_t soft_prst1; |
| cvmx_ciu_soft_prst_t soft_prst; |
| cvmx_mio_rst_ctlx_t rst_ctl; |
| |
| if (pcie_port) { |
| soft_prst1.u64 = csr_rd(CVMX_CIU_SOFT_PRST1); |
| soft_prst1.s.soft_prst = 1; |
| csr_wr(CVMX_CIU_SOFT_PRST1, soft_prst1.u64); |
| } else { |
| soft_prst.u64 = csr_rd(CVMX_CIU_SOFT_PRST); |
| soft_prst.s.soft_prst = 1; |
| csr_wr(CVMX_CIU_SOFT_PRST, soft_prst.u64); |
| } |
| |
| rst_ctl.u64 = csr_rd(CVMX_MIO_RST_CTLX(pcie_port)); |
| |
| rst_ctl.s.prst_link = rc; |
| rst_ctl.s.rst_link = ep; |
| rst_ctl.s.prtmode = rc; |
| rst_ctl.s.rst_drv = rc; |
| rst_ctl.s.rst_rcv = 0; |
| rst_ctl.s.rst_chip = ep; |
| csr_wr(CVMX_MIO_RST_CTLX(pcie_port), rst_ctl.u64); |
| |
| if (root_complex == 0) { |
| if (pcie_port) { |
| soft_prst1.u64 = csr_rd(CVMX_CIU_SOFT_PRST1); |
| soft_prst1.s.soft_prst = 0; |
| csr_wr(CVMX_CIU_SOFT_PRST1, soft_prst1.u64); |
| } else { |
| soft_prst.u64 = csr_rd(CVMX_CIU_SOFT_PRST); |
| soft_prst.s.soft_prst = 0; |
| csr_wr(CVMX_CIU_SOFT_PRST, soft_prst.u64); |
| } |
| } |
| } |
| |
| /** |
| * Configure qlm speed and mode. MIO_QLMX_CFG[speed,mode] are not set |
| * for CN61XX. |
| * |
| * @param qlm The QLM to configure |
| * @param speed The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * QLM 0: 0 = PCIe0 1X4, 1 = Reserved, 2 = SGMII1, 3 = XAUI1 |
| * QLM 1: 0 = PCIe1 1x2, 1 = PCIe(0/1) 2x1, 2 - 3 = Reserved |
| * QLM 2: 0 - 1 = Reserved, 2 = SGMII0, 3 = XAUI0 |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP |
| * mode. |
| * @param pcie2x1 Only used when QLM1 is in PCIE2x1 mode. The QLM_SPD has a |
| * different value on how PEMx needs to be configured: |
| * 0x0 - both PEM0 & PEM1 are in gen1 mode. |
| * 0x1 - PEM0 in gen2 and PEM1 in gen1 mode. |
| * 0x2 - PEM0 in gen1 and PEM1 in gen2 mode. |
| * 0x3 - both PEM0 & PEM1 are in gen2 mode. |
| * SPEED value is ignored in this mode. QLM_SPD is set based on |
| * pcie2x1 value in this mode. |
| * |
| * @return Return 0 on success or -1. |
| */ |
| static int octeon_configure_qlm_cn61xx(int qlm, int speed, int mode, int rc, int pcie2x1) |
| { |
| cvmx_mio_qlmx_cfg_t qlm_cfg; |
| |
| /* The QLM speed varies for SGMII/XAUI and PCIe mode. And depends on |
| * reference clock. |
| */ |
| if (!OCTEON_IS_MODEL(OCTEON_CN61XX)) |
| return -1; |
| |
| if (qlm < 3) { |
| qlm_cfg.u64 = csr_rd(CVMX_MIO_QLMX_CFG(qlm)); |
| } else { |
| debug("WARNING: Invalid QLM(%d) passed\n", qlm); |
| return -1; |
| } |
| |
| switch (qlm) { |
| /* SGMII/XAUI mode */ |
| case 2: { |
| if (mode < 2) { |
| qlm_cfg.s.qlm_spd = 0xf; |
| break; |
| } |
| qlm_cfg.s.qlm_spd = __get_qlm_spd(qlm, speed); |
| qlm_cfg.s.qlm_cfg = mode; |
| break; |
| } |
| case 1: { |
| if (mode == 1) { /* 2x1 mode */ |
| cvmx_mio_qlmx_cfg_t qlm0; |
| |
| /* When QLM0 is configured as PCIe(QLM_CFG=0x0) |
| * and enabled (QLM_SPD != 0xf), QLM1 cannot be |
| * configured as PCIe 2x1 mode (QLM_CFG=0x1) |
| * and enabled (QLM_SPD != 0xf). |
| */ |
| qlm0.u64 = csr_rd(CVMX_MIO_QLMX_CFG(0)); |
| if (qlm0.s.qlm_spd != 0xf && qlm0.s.qlm_cfg == 0) { |
| debug("Invalid mode(%d) for QLM(%d) as QLM1 is PCIe mode\n", |
| mode, qlm); |
| qlm_cfg.s.qlm_spd = 0xf; |
| break; |
| } |
| |
| /* Set QLM_SPD based on reference clock and mode */ |
| if (cvmx_qlm_is_ref_clock(qlm, 100)) { |
| if (pcie2x1 == 0x3) |
| qlm_cfg.s.qlm_spd = 0x0; |
| else if (pcie2x1 == 0x1) |
| qlm_cfg.s.qlm_spd = 0x2; |
| else if (pcie2x1 == 0x2) |
| qlm_cfg.s.qlm_spd = 0x1; |
| else if (pcie2x1 == 0x0) |
| qlm_cfg.s.qlm_spd = 0x3; |
| else |
| qlm_cfg.s.qlm_spd = 0xf; |
| } else if (cvmx_qlm_is_ref_clock(qlm, 125)) { |
| if (pcie2x1 == 0x3) |
| qlm_cfg.s.qlm_spd = 0x4; |
| else if (pcie2x1 == 0x1) |
| qlm_cfg.s.qlm_spd = 0x6; |
| else if (pcie2x1 == 0x2) |
| qlm_cfg.s.qlm_spd = 0x9; |
| else if (pcie2x1 == 0x0) |
| qlm_cfg.s.qlm_spd = 0x7; |
| else |
| qlm_cfg.s.qlm_spd = 0xf; |
| } |
| qlm_cfg.s.qlm_cfg = mode; |
| csr_wr(CVMX_MIO_QLMX_CFG(qlm), qlm_cfg.u64); |
| |
| /* Set PCIe mode bits */ |
| __set_qlm_pcie_mode_61xx(0, rc); |
| __set_qlm_pcie_mode_61xx(1, rc); |
| return 0; |
| } else if (mode > 1) { |
| debug("Invalid mode(%d) for QLM(%d).\n", mode, qlm); |
| qlm_cfg.s.qlm_spd = 0xf; |
| break; |
| } |
| |
| /* Set speed and mode for PCIe 1x2 mode. */ |
| if (cvmx_qlm_is_ref_clock(qlm, 100)) { |
| if (speed == 5000) |
| qlm_cfg.s.qlm_spd = 0x1; |
| else if (speed == 2500) |
| qlm_cfg.s.qlm_spd = 0x2; |
| else |
| qlm_cfg.s.qlm_spd = 0xf; |
| } else if (cvmx_qlm_is_ref_clock(qlm, 125)) { |
| if (speed == 5000) |
| qlm_cfg.s.qlm_spd = 0x4; |
| else if (speed == 2500) |
| qlm_cfg.s.qlm_spd = 0x6; |
| else |
| qlm_cfg.s.qlm_spd = 0xf; |
| } else { |
| qlm_cfg.s.qlm_spd = 0xf; |
| } |
| |
| qlm_cfg.s.qlm_cfg = mode; |
| csr_wr(CVMX_MIO_QLMX_CFG(qlm), qlm_cfg.u64); |
| |
| /* Set PCIe mode bits */ |
| __set_qlm_pcie_mode_61xx(1, rc); |
| return 0; |
| } |
| case 0: { |
| /* QLM_CFG = 0x1 - Reserved */ |
| if (mode == 1) { |
| qlm_cfg.s.qlm_spd = 0xf; |
| break; |
| } |
| /* QLM_CFG = 0x0 - PCIe 1x4(PEM0) */ |
| if (mode == 0 && speed != 5000 && speed != 2500) { |
| qlm_cfg.s.qlm_spd = 0xf; |
| break; |
| } |
| |
| /* Set speed and mode */ |
| qlm_cfg.s.qlm_spd = __get_qlm_spd(qlm, speed); |
| qlm_cfg.s.qlm_cfg = mode; |
| csr_wr(CVMX_MIO_QLMX_CFG(qlm), qlm_cfg.u64); |
| |
| /* Set PCIe mode bits */ |
| if (mode == 0) |
| __set_qlm_pcie_mode_61xx(0, rc); |
| |
| return 0; |
| } |
| default: |
| debug("WARNING: Invalid QLM(%d) passed\n", qlm); |
| qlm_cfg.s.qlm_spd = 0xf; |
| } |
| csr_wr(CVMX_MIO_QLMX_CFG(qlm), qlm_cfg.u64); |
| return 0; |
| } |
| |
| /* qlm : DLM to configure |
| * baud_mhz : speed of the DLM |
| * ref_clk_sel : reference clock speed selection where: |
| * 0: 100MHz |
| * 1: 125MHz |
| * 2: 156.25MHz |
| * |
| * ref_clk_input: reference clock input where: |
| * 0: DLMC_REF_CLK0_[P,N] |
| * 1: DLMC_REF_CLK1_[P,N] |
| * 2: DLM0_REF_CLK_[P,N] (only valid for QLM 0) |
| * is_sff7000_rxaui : boolean to indicate whether qlm is RXAUI on SFF7000 |
| */ |
| static int __dlm_setup_pll_cn70xx(int qlm, int baud_mhz, int ref_clk_sel, int ref_clk_input, |
| int is_sff7000_rxaui) |
| { |
| cvmx_gserx_dlmx_test_powerdown_t dlmx_test_powerdown; |
| cvmx_gserx_dlmx_ref_ssp_en_t dlmx_ref_ssp_en; |
| cvmx_gserx_dlmx_mpll_en_t dlmx_mpll_en; |
| cvmx_gserx_dlmx_phy_reset_t dlmx_phy_reset; |
| cvmx_gserx_dlmx_tx_amplitude_t tx_amplitude; |
| cvmx_gserx_dlmx_tx_preemph_t tx_preemph; |
| cvmx_gserx_dlmx_rx_eq_t rx_eq; |
| cvmx_gserx_dlmx_ref_clkdiv2_t ref_clkdiv2; |
| cvmx_gserx_dlmx_mpll_multiplier_t mpll_multiplier; |
| int gmx_ref_clk = 100; |
| |
| debug("%s(%d, %d, %d, %d, %d)\n", __func__, qlm, baud_mhz, ref_clk_sel, ref_clk_input, |
| is_sff7000_rxaui); |
| if (ref_clk_sel == 1) |
| gmx_ref_clk = 125; |
| else if (ref_clk_sel == 2) |
| gmx_ref_clk = 156; |
| |
| if (qlm != 0 && ref_clk_input == 2) { |
| printf("%s: Error: can only use reference clock inputs 0 or 1 for DLM %d\n", |
| __func__, qlm); |
| return -1; |
| } |
| |
| /* Hardware defaults are invalid */ |
| tx_amplitude.u64 = csr_rd(CVMX_GSERX_DLMX_TX_AMPLITUDE(qlm, 0)); |
| if (is_sff7000_rxaui) { |
| tx_amplitude.s.tx0_amplitude = 100; |
| tx_amplitude.s.tx1_amplitude = 100; |
| } else { |
| tx_amplitude.s.tx0_amplitude = 65; |
| tx_amplitude.s.tx1_amplitude = 65; |
| } |
| |
| csr_wr(CVMX_GSERX_DLMX_TX_AMPLITUDE(qlm, 0), tx_amplitude.u64); |
| |
| tx_preemph.u64 = csr_rd(CVMX_GSERX_DLMX_TX_PREEMPH(qlm, 0)); |
| |
| if (is_sff7000_rxaui) { |
| tx_preemph.s.tx0_preemph = 0; |
| tx_preemph.s.tx1_preemph = 0; |
| } else { |
| tx_preemph.s.tx0_preemph = 22; |
| tx_preemph.s.tx1_preemph = 22; |
| } |
| csr_wr(CVMX_GSERX_DLMX_TX_PREEMPH(qlm, 0), tx_preemph.u64); |
| |
| rx_eq.u64 = csr_rd(CVMX_GSERX_DLMX_RX_EQ(qlm, 0)); |
| rx_eq.s.rx0_eq = 0; |
| rx_eq.s.rx1_eq = 0; |
| csr_wr(CVMX_GSERX_DLMX_RX_EQ(qlm, 0), rx_eq.u64); |
| |
| /* 1. Write GSER0_DLM0_REF_USE_PAD[REF_USE_PAD] = 1 (to select |
| * reference-clock input) |
| * The documentation for this register in the HRM is useless since |
| * it says it selects between two different clocks that are not |
| * documented anywhere. What it really does is select between |
| * DLM0_REF_CLK_[P,N] if 1 and DLMC_REF_CLK[0,1]_[P,N] if 0. |
| * |
| * This register must be 0 for DLMs 1 and 2 and can only be 1 for |
| * DLM 0. |
| */ |
| csr_wr(CVMX_GSERX_DLMX_REF_USE_PAD(0, 0), ((ref_clk_input == 2) && (qlm == 0)) ? 1 : 0); |
| |
| /* Reference clock was already chosen before we got here */ |
| |
| /* 2. Write GSER0_DLM0_REFCLK_SEL[REFCLK_SEL] if required for |
| * reference-clock selection. |
| * |
| * If GSERX_DLMX_REF_USE_PAD is 1 then this register is ignored. |
| */ |
| csr_wr(CVMX_GSERX_DLMX_REFCLK_SEL(0, 0), ref_clk_input & 1); |
| |
| /* Reference clock was already chosen before we got here */ |
| |
| /* 3. If required, write GSER0_DLM0_REF_CLKDIV2[REF_CLKDIV2] (must be |
| * set if reference clock > 100 MHz) |
| */ |
| /* Apply workaround for Errata (G-20669) MPLL may not come up. */ |
| ref_clkdiv2.u64 = csr_rd(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0)); |
| if (gmx_ref_clk == 100) |
| ref_clkdiv2.s.ref_clkdiv2 = 0; |
| else |
| ref_clkdiv2.s.ref_clkdiv2 = 1; |
| csr_wr(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0), ref_clkdiv2.u64); |
| |
| /* 1. Ensure GSER(0)_DLM(0..2)_PHY_RESET[PHY_RESET] is set. */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 2. If SGMII or QSGMII or RXAUI (i.e. if DLM0) set |
| * GSER(0)_DLM(0)_MPLL_EN[MPLL_EN] to one. |
| */ |
| /* 7. Set GSER0_DLM0_MPLL_EN[MPLL_EN] = 1 */ |
| dlmx_mpll_en.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_EN(0, 0)); |
| dlmx_mpll_en.s.mpll_en = 1; |
| csr_wr(CVMX_GSERX_DLMX_MPLL_EN(0, 0), dlmx_mpll_en.u64); |
| |
| /* 3. Set GSER(0)_DLM(0..2)_MPLL_MULTIPLIER[MPLL_MULTIPLIER] |
| * to the value in the preceding table, which is different |
| * than the desired setting prescribed by the HRM. |
| */ |
| mpll_multiplier.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0)); |
| if (gmx_ref_clk == 100) |
| mpll_multiplier.s.mpll_multiplier = 35; |
| else if (gmx_ref_clk == 125) |
| mpll_multiplier.s.mpll_multiplier = 56; |
| else |
| mpll_multiplier.s.mpll_multiplier = 45; |
| debug("%s: Setting mpll multiplier to %u for DLM%d, baud %d, clock rate %uMHz\n", |
| __func__, mpll_multiplier.s.mpll_multiplier, qlm, baud_mhz, gmx_ref_clk); |
| |
| csr_wr(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0), mpll_multiplier.u64); |
| |
| /* 5. Clear GSER0_DLM0_TEST_POWERDOWN[TEST_POWERDOWN] */ |
| dlmx_test_powerdown.u64 = csr_rd(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0)); |
| dlmx_test_powerdown.s.test_powerdown = 0; |
| csr_wr(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0), dlmx_test_powerdown.u64); |
| |
| /* 6. Set GSER0_DLM0_REF_SSP_EN[REF_SSP_EN] = 1 */ |
| dlmx_ref_ssp_en.u64 = csr_rd(CVMX_GSERX_DLMX_REF_SSP_EN(qlm, 0)); |
| dlmx_ref_ssp_en.s.ref_ssp_en = 1; |
| csr_wr(CVMX_GSERX_DLMX_REF_SSP_EN(0, 0), dlmx_ref_ssp_en.u64); |
| |
| /* 8. Clear GSER0_DLM0_PHY_RESET[PHY_RESET] = 0 */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 5. If PCIe or SATA (i.e. if DLM1 or DLM2), set both MPLL_EN |
| * and MPLL_EN_OVRD to one in GSER(0)_PHY(1..2)_OVRD_IN_LO. |
| */ |
| |
| /* 6. Decrease MPLL_MULTIPLIER by one continually until it |
| * reaches the desired long-term setting, ensuring that each |
| * MPLL_MULTIPLIER value is constant for at least 1 msec before |
| * changing to the next value. The desired long-term setting is |
| * as indicated in HRM tables 21-1, 21-2, and 21-3. This is not |
| * required with the HRM sequence. |
| */ |
| mpll_multiplier.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0)); |
| __cvmx_qlm_set_mult(qlm, baud_mhz, mpll_multiplier.s.mpll_multiplier); |
| |
| /* 9. Poll until the MPLL locks. Wait for |
| * GSER0_DLM0_MPLL_STATUS[MPLL_STATUS] = 1 |
| */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_MPLL_STATUS(qlm, 0), |
| cvmx_gserx_dlmx_mpll_status_t, mpll_status, ==, 1, 10000)) { |
| printf("PLL for DLM%d failed to lock\n", qlm); |
| return -1; |
| } |
| return 0; |
| } |
| |
| static int __dlm0_setup_tx_cn70xx(int speed, int ref_clk_sel) |
| { |
| int need0, need1; |
| cvmx_gmxx_inf_mode_t mode0, mode1; |
| cvmx_gserx_dlmx_tx_rate_t rate; |
| cvmx_gserx_dlmx_tx_en_t en; |
| cvmx_gserx_dlmx_tx_cm_en_t cm_en; |
| cvmx_gserx_dlmx_tx_data_en_t data_en; |
| cvmx_gserx_dlmx_tx_reset_t tx_reset; |
| |
| debug("%s(%d, %d)\n", __func__, speed, ref_clk_sel); |
| mode0.u64 = csr_rd(CVMX_GMXX_INF_MODE(0)); |
| mode1.u64 = csr_rd(CVMX_GMXX_INF_MODE(1)); |
| |
| /* Which lanes do we need? */ |
| need0 = (mode0.s.mode != CVMX_GMX_INF_MODE_DISABLED); |
| need1 = (mode1.s.mode != CVMX_GMX_INF_MODE_DISABLED) || |
| (mode0.s.mode == CVMX_GMX_INF_MODE_RXAUI); |
| |
| /* 1. Write GSER0_DLM0_TX_RATE[TXn_RATE] (Set according to required |
| * data rate (see Table 21-1). |
| */ |
| rate.u64 = csr_rd(CVMX_GSERX_DLMX_TX_RATE(0, 0)); |
| debug("%s: speed: %d\n", __func__, speed); |
| switch (speed) { |
| case 1250: |
| case 2500: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_100MHZ: /* 100MHz */ |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.tx0_rate = (mode0.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 2 : 0; |
| rate.s.tx1_rate = (mode1.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 2 : 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 3125: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.tx0_rate = (mode0.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 1 : 0; |
| rate.s.tx1_rate = (mode1.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 1 : 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 5000: /* QSGMII only */ |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_100MHZ: /* 100MHz */ |
| rate.s.tx0_rate = 0; |
| rate.s.tx1_rate = 0; |
| break; |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.tx0_rate = 0; |
| rate.s.tx1_rate = 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 6250: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.tx0_rate = 0; |
| rate.s.tx1_rate = 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| default: |
| printf("%s: Invalid rate %d\n", __func__, speed); |
| return -1; |
| } |
| debug("%s: tx 0 rate: %d, tx 1 rate: %d\n", __func__, rate.s.tx0_rate, rate.s.tx1_rate); |
| csr_wr(CVMX_GSERX_DLMX_TX_RATE(0, 0), rate.u64); |
| |
| /* 2. Set GSER0_DLM0_TX_EN[TXn_EN] = 1 */ |
| en.u64 = csr_rd(CVMX_GSERX_DLMX_TX_EN(0, 0)); |
| en.s.tx0_en = need0; |
| en.s.tx1_en = need1; |
| csr_wr(CVMX_GSERX_DLMX_TX_EN(0, 0), en.u64); |
| |
| /* 3 set GSER0_DLM0_TX_CM_EN[TXn_CM_EN] = 1 */ |
| cm_en.u64 = csr_rd(CVMX_GSERX_DLMX_TX_CM_EN(0, 0)); |
| cm_en.s.tx0_cm_en = need0; |
| cm_en.s.tx1_cm_en = need1; |
| csr_wr(CVMX_GSERX_DLMX_TX_CM_EN(0, 0), cm_en.u64); |
| |
| /* 4. Set GSER0_DLM0_TX_DATA_EN[TXn_DATA_EN] = 1 */ |
| data_en.u64 = csr_rd(CVMX_GSERX_DLMX_TX_DATA_EN(0, 0)); |
| data_en.s.tx0_data_en = need0; |
| data_en.s.tx1_data_en = need1; |
| csr_wr(CVMX_GSERX_DLMX_TX_DATA_EN(0, 0), data_en.u64); |
| |
| /* 5. Clear GSER0_DLM0_TX_RESET[TXn_DATA_EN] = 0 */ |
| tx_reset.u64 = csr_rd(CVMX_GSERX_DLMX_TX_RESET(0, 0)); |
| tx_reset.s.tx0_reset = !need0; |
| tx_reset.s.tx1_reset = !need1; |
| csr_wr(CVMX_GSERX_DLMX_TX_RESET(0, 0), tx_reset.u64); |
| |
| /* 6. Poll GSER0_DLM0_TX_STATUS[TXn_STATUS, TXn_CM_STATUS] until both |
| * are set to 1. This prevents GMX from transmitting until the DLM |
| * is ready. |
| */ |
| if (need0) { |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_TX_STATUS(0, 0), |
| cvmx_gserx_dlmx_tx_status_t, tx0_status, ==, 1, 10000)) { |
| printf("DLM0 TX0 status fail\n"); |
| return -1; |
| } |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_TX_STATUS(0, 0), |
| cvmx_gserx_dlmx_tx_status_t, tx0_cm_status, ==, 1, |
| 10000)) { |
| printf("DLM0 TX0 CM status fail\n"); |
| return -1; |
| } |
| } |
| if (need1) { |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_TX_STATUS(0, 0), |
| cvmx_gserx_dlmx_tx_status_t, tx1_status, ==, 1, 10000)) { |
| printf("DLM0 TX1 status fail\n"); |
| return -1; |
| } |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_TX_STATUS(0, 0), |
| cvmx_gserx_dlmx_tx_status_t, tx1_cm_status, ==, 1, |
| 10000)) { |
| printf("DLM0 TX1 CM status fail\n"); |
| return -1; |
| } |
| } |
| return 0; |
| } |
| |
| static int __dlm0_setup_rx_cn70xx(int speed, int ref_clk_sel) |
| { |
| int need0, need1; |
| cvmx_gmxx_inf_mode_t mode0, mode1; |
| cvmx_gserx_dlmx_rx_rate_t rate; |
| cvmx_gserx_dlmx_rx_pll_en_t pll_en; |
| cvmx_gserx_dlmx_rx_data_en_t data_en; |
| cvmx_gserx_dlmx_rx_reset_t rx_reset; |
| |
| debug("%s(%d, %d)\n", __func__, speed, ref_clk_sel); |
| mode0.u64 = csr_rd(CVMX_GMXX_INF_MODE(0)); |
| mode1.u64 = csr_rd(CVMX_GMXX_INF_MODE(1)); |
| |
| /* Which lanes do we need? */ |
| need0 = (mode0.s.mode != CVMX_GMX_INF_MODE_DISABLED); |
| need1 = (mode1.s.mode != CVMX_GMX_INF_MODE_DISABLED) || |
| (mode0.s.mode == CVMX_GMX_INF_MODE_RXAUI); |
| |
| /* 1. Write GSER0_DLM0_RX_RATE[RXn_RATE] (must match the |
| * GER0_DLM0_TX_RATE[TXn_RATE] setting). |
| */ |
| rate.u64 = csr_rd(CVMX_GSERX_DLMX_RX_RATE(0, 0)); |
| switch (speed) { |
| case 1250: |
| case 2500: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_100MHZ: /* 100MHz */ |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.rx0_rate = (mode0.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 2 : 0; |
| rate.s.rx1_rate = (mode1.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 2 : 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 3125: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.rx0_rate = (mode0.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 1 : 0; |
| rate.s.rx1_rate = (mode1.s.mode == CVMX_GMX_INF_MODE_SGMII) ? 1 : 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 5000: /* QSGMII only */ |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_100MHZ: /* 100MHz */ |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.rx0_rate = 0; |
| rate.s.rx1_rate = 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| case 6250: |
| switch (ref_clk_sel) { |
| case OCTEON_QLM_REF_CLK_125MHZ: /* 125MHz */ |
| case OCTEON_QLM_REF_CLK_156MHZ: /* 156.25MHz */ |
| rate.s.rx0_rate = 0; |
| rate.s.rx1_rate = 0; |
| break; |
| default: |
| printf("Invalid reference clock select %d\n", ref_clk_sel); |
| return -1; |
| } |
| break; |
| default: |
| printf("%s: Invalid rate %d\n", __func__, speed); |
| return -1; |
| } |
| debug("%s: rx 0 rate: %d, rx 1 rate: %d\n", __func__, rate.s.rx0_rate, rate.s.rx1_rate); |
| csr_wr(CVMX_GSERX_DLMX_RX_RATE(0, 0), rate.u64); |
| |
| /* 2. Set GSER0_DLM0_RX_PLL_EN[RXn_PLL_EN] = 1 */ |
| pll_en.u64 = csr_rd(CVMX_GSERX_DLMX_RX_PLL_EN(0, 0)); |
| pll_en.s.rx0_pll_en = need0; |
| pll_en.s.rx1_pll_en = need1; |
| csr_wr(CVMX_GSERX_DLMX_RX_PLL_EN(0, 0), pll_en.u64); |
| |
| /* 3. Set GSER0_DLM0_RX_DATA_EN[RXn_DATA_EN] = 1 */ |
| data_en.u64 = csr_rd(CVMX_GSERX_DLMX_RX_DATA_EN(0, 0)); |
| data_en.s.rx0_data_en = need0; |
| data_en.s.rx1_data_en = need1; |
| csr_wr(CVMX_GSERX_DLMX_RX_DATA_EN(0, 0), data_en.u64); |
| |
| /* 4. Clear GSER0_DLM0_RX_RESET[RXn_DATA_EN] = 0. Now the GMX can be |
| * enabled: set GMX(0..1)_INF_MODE[EN] = 1 |
| */ |
| rx_reset.u64 = csr_rd(CVMX_GSERX_DLMX_RX_RESET(0, 0)); |
| rx_reset.s.rx0_reset = !need0; |
| rx_reset.s.rx1_reset = !need1; |
| csr_wr(CVMX_GSERX_DLMX_RX_RESET(0, 0), rx_reset.u64); |
| |
| return 0; |
| } |
| |
| static int a_clk; |
| |
| static int __dlm2_sata_uctl_init_cn70xx(void) |
| { |
| cvmx_sata_uctl_ctl_t uctl_ctl; |
| const int MAX_A_CLK = 333000000; /* Max of 333Mhz */ |
| int divisor, a_clkdiv; |
| |
| /* Wait for all voltages to reach a stable stable. Ensure the |
| * reference clock is up and stable. |
| */ |
| |
| /* 2. Wait for IOI reset to deassert. */ |
| |
| /* 3. Optionally program the GPIO CSRs for SATA features. |
| * a. For cold-presence detect: |
| * i. Select a GPIO for the input and program GPIO_SATA_CTL[sel] |
| * for port0 and port1. |
| * ii. Select a GPIO for the output and program |
| * GPIO_BIT_CFG*[OUTPUT_SEL] for port0 and port1. |
| * b. For mechanical-presence detect, select a GPIO for the input |
| * and program GPIO_SATA_CTL[SEL] for port0/port1. |
| * c. For LED activity, select a GPIO for the output and program |
| * GPIO_BIT_CFG*[OUTPUT_SEL] for port0/port1. |
| */ |
| |
| /* 4. Assert all resets: |
| * a. UAHC reset: SATA_UCTL_CTL[UAHC_RST] = 1 |
| * a. UCTL reset: SATA_UCTL_CTL[UCTL_RST] = 1 |
| */ |
| |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.sata_uahc_rst = 1; |
| uctl_ctl.s.sata_uctl_rst = 1; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| /* 5. Configure the ACLK: |
| * a. Reset the clock dividers: SATA_UCTL_CTL[A_CLKDIV_RST] = 1. |
| * b. Select the ACLK frequency (400 MHz maximum) |
| * i. SATA_UCTL_CTL[A_CLKDIV] = desired value, |
| * ii. SATA_UCTL_CTL[A_CLKDIV_EN] = 1 to enable the ACLK, |
| * c. Deassert the ACLK clock divider reset: |
| * SATA_UCTL_CTL[A_CLKDIV_RST] = 0 |
| */ |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.a_clkdiv_rst = 1; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| |
| divisor = (gd->bus_clk + MAX_A_CLK - 1) / MAX_A_CLK; |
| if (divisor <= 4) { |
| a_clkdiv = divisor - 1; |
| } else if (divisor <= 6) { |
| a_clkdiv = 4; |
| divisor = 6; |
| } else if (divisor <= 8) { |
| a_clkdiv = 5; |
| divisor = 8; |
| } else if (divisor <= 16) { |
| a_clkdiv = 6; |
| divisor = 16; |
| } else if (divisor <= 24) { |
| a_clkdiv = 7; |
| divisor = 24; |
| } else { |
| printf("Unable to determine SATA clock divisor\n"); |
| return -1; |
| } |
| |
| /* Calculate the final clock rate */ |
| a_clk = gd->bus_clk / divisor; |
| |
| uctl_ctl.s.a_clkdiv_sel = a_clkdiv; |
| uctl_ctl.s.a_clk_en = 1; |
| uctl_ctl.s.a_clk_byp_sel = 0; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.a_clkdiv_rst = 0; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| udelay(1); |
| |
| return 0; |
| } |
| |
| static int __sata_dlm_init_cn70xx(int qlm, int baud_mhz, int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_gserx_sata_cfg_t sata_cfg; |
| cvmx_gserx_sata_lane_rst_t sata_lane_rst; |
| cvmx_gserx_dlmx_phy_reset_t dlmx_phy_reset; |
| cvmx_gserx_dlmx_test_powerdown_t dlmx_test_powerdown; |
| cvmx_gserx_sata_ref_ssp_en_t ref_ssp_en; |
| cvmx_gserx_dlmx_mpll_multiplier_t mpll_multiplier; |
| cvmx_gserx_dlmx_ref_clkdiv2_t ref_clkdiv2; |
| cvmx_sata_uctl_shim_cfg_t shim_cfg; |
| cvmx_gserx_phyx_ovrd_in_lo_t ovrd_in; |
| cvmx_sata_uctl_ctl_t uctl_ctl; |
| int sata_ref_clk; |
| |
| debug("%s(%d, %d, %d, %d)\n", __func__, qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| |
| switch (ref_clk_sel) { |
| case 0: |
| sata_ref_clk = 100; |
| break; |
| case 1: |
| sata_ref_clk = 125; |
| break; |
| case 2: |
| sata_ref_clk = 156; |
| break; |
| default: |
| printf("%s: Invalid reference clock select %d for qlm %d\n", __func__, |
| ref_clk_sel, qlm); |
| return -1; |
| } |
| |
| /* 5. Set GSERX0_SATA_CFG[SATA_EN] = 1 to configure DLM2 multiplexing. |
| */ |
| sata_cfg.u64 = csr_rd(CVMX_GSERX_SATA_CFG(0)); |
| sata_cfg.s.sata_en = 1; |
| csr_wr(CVMX_GSERX_SATA_CFG(0), sata_cfg.u64); |
| |
| /* 1. Write GSER(0)_DLM2_REFCLK_SEL[REFCLK_SEL] if required for |
| * reference-clock selection. |
| */ |
| if (ref_clk_input < 2) { |
| csr_wr(CVMX_GSERX_DLMX_REFCLK_SEL(qlm, 0), ref_clk_input); |
| csr_wr(CVMX_GSERX_DLMX_REF_USE_PAD(qlm, 0), 0); |
| } else { |
| csr_wr(CVMX_GSERX_DLMX_REF_USE_PAD(qlm, 0), 1); |
| } |
| |
| ref_ssp_en.u64 = csr_rd(CVMX_GSERX_SATA_REF_SSP_EN(0)); |
| ref_ssp_en.s.ref_ssp_en = 1; |
| csr_wr(CVMX_GSERX_SATA_REF_SSP_EN(0), ref_ssp_en.u64); |
| |
| /* Apply workaround for Errata (G-20669) MPLL may not come up. */ |
| |
| /* Set REF_CLKDIV2 based on the Ref Clock */ |
| ref_clkdiv2.u64 = csr_rd(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0)); |
| if (sata_ref_clk == 100) |
| ref_clkdiv2.s.ref_clkdiv2 = 0; |
| else |
| ref_clkdiv2.s.ref_clkdiv2 = 1; |
| csr_wr(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0), ref_clkdiv2.u64); |
| |
| /* 1. Ensure GSER(0)_DLM(0..2)_PHY_RESET[PHY_RESET] is set. */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 2. If SGMII or QSGMII or RXAUI (i.e. if DLM0) set |
| * GSER(0)_DLM(0)_MPLL_EN[MPLL_EN] to one. |
| */ |
| |
| /* 3. Set GSER(0)_DLM(0..2)_MPLL_MULTIPLIER[MPLL_MULTIPLIER] |
| * to the value in the preceding table, which is different |
| * than the desired setting prescribed by the HRM. |
| */ |
| |
| mpll_multiplier.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0)); |
| if (sata_ref_clk == 100) |
| mpll_multiplier.s.mpll_multiplier = 35; |
| else |
| mpll_multiplier.s.mpll_multiplier = 56; |
| csr_wr(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0), mpll_multiplier.u64); |
| |
| /* 3. Clear GSER0_DLM2_TEST_POWERDOWN[TEST_POWERDOWN] = 0 */ |
| dlmx_test_powerdown.u64 = csr_rd(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0)); |
| dlmx_test_powerdown.s.test_powerdown = 0; |
| csr_wr(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0), dlmx_test_powerdown.u64); |
| |
| /* 4. Clear either/both lane0 and lane1 resets: |
| * GSER0_SATA_LANE_RST[L0_RST, L1_RST] = 0. |
| */ |
| sata_lane_rst.u64 = csr_rd(CVMX_GSERX_SATA_LANE_RST(0)); |
| sata_lane_rst.s.l0_rst = 0; |
| sata_lane_rst.s.l1_rst = 0; |
| csr_wr(CVMX_GSERX_SATA_LANE_RST(0), sata_lane_rst.u64); |
| |
| udelay(1); |
| |
| /* 5. Clear GSER0_DLM2_PHY_RESET */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 6. If PCIe or SATA (i.e. if DLM1 or DLM2), set both MPLL_EN |
| * and MPLL_EN_OVRD to one in GSER(0)_PHY(1..2)_OVRD_IN_LO. |
| */ |
| ovrd_in.u64 = csr_rd(CVMX_GSERX_PHYX_OVRD_IN_LO(qlm, 0)); |
| ovrd_in.s.mpll_en = 1; |
| ovrd_in.s.mpll_en_ovrd = 1; |
| csr_wr(CVMX_GSERX_PHYX_OVRD_IN_LO(qlm, 0), ovrd_in.u64); |
| |
| /* 7. Decrease MPLL_MULTIPLIER by one continually until it reaches |
| * the desired long-term setting, ensuring that each MPLL_MULTIPLIER |
| * value is constant for at least 1 msec before changing to the next |
| * value. The desired long-term setting is as indicated in HRM tables |
| * 21-1, 21-2, and 21-3. This is not required with the HRM |
| * sequence. |
| */ |
| mpll_multiplier.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0)); |
| if (sata_ref_clk == 100) |
| mpll_multiplier.s.mpll_multiplier = 0x1e; |
| else |
| mpll_multiplier.s.mpll_multiplier = 0x30; |
| csr_wr(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0), mpll_multiplier.u64); |
| |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_MPLL_STATUS(qlm, 0), |
| cvmx_gserx_dlmx_mpll_status_t, mpll_status, ==, 1, 10000)) { |
| printf("ERROR: SATA MPLL failed to set\n"); |
| return -1; |
| } |
| |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_RX_STATUS(qlm, 0), cvmx_gserx_dlmx_rx_status_t, |
| rx0_status, ==, 1, 10000)) { |
| printf("ERROR: SATA RX0_STATUS failed to set\n"); |
| return -1; |
| } |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_DLMX_RX_STATUS(qlm, 0), cvmx_gserx_dlmx_rx_status_t, |
| rx1_status, ==, 1, 10000)) { |
| printf("ERROR: SATA RX1_STATUS failed to set\n"); |
| return -1; |
| } |
| |
| /* 8. Deassert UCTL and UAHC resets: |
| * a. SATA_UCTL_CTL[UCTL_RST] = 0 |
| * b. SATA_UCTL_CTL[UAHC_RST] = 0 |
| * c. Wait 10 ACLK cycles before accessing any ACLK-only registers. |
| */ |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.sata_uctl_rst = 0; |
| uctl_ctl.s.sata_uahc_rst = 0; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| udelay(1); |
| |
| /* 9. Enable conditional SCLK of UCTL by writing |
| * SATA_UCTL_CTL[CSCLK_EN] = 1 |
| */ |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.csclk_en = 1; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| /* 10. Initialize UAHC as described in the AHCI Specification (UAHC_* |
| * registers |
| */ |
| |
| /* set-up endian mode */ |
| shim_cfg.u64 = csr_rd(CVMX_SATA_UCTL_SHIM_CFG); |
| shim_cfg.s.dma_endian_mode = 1; |
| shim_cfg.s.csr_endian_mode = 3; |
| csr_wr(CVMX_SATA_UCTL_SHIM_CFG, shim_cfg.u64); |
| |
| return 0; |
| } |
| |
| /** |
| * Initializes DLM 4 for SATA |
| * |
| * @param qlm Must be 4. |
| * @param baud_mhz Baud rate for SATA |
| * @param ref_clk_sel Selects the speed of the reference clock where: |
| * 0 = 100MHz, 1 = 125MHz and 2 = 156.25MHz |
| * @param ref_clk_input Reference clock input where 0 = external QLM clock, |
| * 1 = qlmc_ref_clk0 and 2 = qlmc_ref_clk1 |
| */ |
| static int __sata_dlm_init_cn73xx(int qlm, int baud_mhz, int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_sata_uctl_shim_cfg_t shim_cfg; |
| cvmx_gserx_refclk_sel_t refclk_sel; |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| cvmx_gserx_rx_pwr_ctrl_p2_t pwr_ctrl_p2; |
| cvmx_gserx_lanex_misc_cfg_0_t misc_cfg_0; |
| cvmx_gserx_sata_lane_rst_t lane_rst; |
| cvmx_gserx_pll_px_mode_0_t pmode_0; |
| cvmx_gserx_pll_px_mode_1_t pmode_1; |
| cvmx_gserx_lane_px_mode_0_t lane_pmode_0; |
| cvmx_gserx_lane_px_mode_1_t lane_pmode_1; |
| cvmx_gserx_cfg_t gserx_cfg; |
| cvmx_sata_uctl_ctl_t uctl_ctl; |
| int l; |
| int i; |
| |
| /* |
| * 1. Configure the SATA |
| */ |
| |
| /* |
| * 2. Configure the QLM Reference clock |
| * Set GSERX_REFCLK_SEL.COM_CLK_SEL to source reference clock |
| * from the external clock mux. |
| * GSERX_REFCLK_SEL.USE_COM1 to select qlmc_refclkn/p_1 or |
| * leave clear to select qlmc_refclkn/p_0 |
| */ |
| refclk_sel.u64 = 0; |
| if (ref_clk_input == 0) { /* External ref clock */ |
| refclk_sel.s.com_clk_sel = 0; |
| refclk_sel.s.use_com1 = 0; |
| } else if (ref_clk_input == 1) { /* Common reference clock 0 */ |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 0; |
| } else { /* Common reference clock 1 */ |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 1; |
| } |
| |
| if (ref_clk_sel != 0) { |
| printf("Wrong reference clock selected for QLM4\n"); |
| return -1; |
| } |
| |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| |
| /* Reset the QLM after changing the reference clock */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| udelay(1); |
| |
| /* |
| * 3. Configure the QLM for SATA mode set GSERX_CFG.SATA |
| */ |
| gserx_cfg.u64 = 0; |
| gserx_cfg.s.sata = 1; |
| csr_wr(CVMX_GSERX_CFG(qlm), gserx_cfg.u64); |
| |
| /* |
| * 12. Clear the appropriate lane resets |
| * clear GSERX_SATA_LANE_RST.LX_RST where X is the lane number 0-1. |
| */ |
| lane_rst.u64 = csr_rd(CVMX_GSERX_SATA_LANE_RST(qlm)); |
| lane_rst.s.l0_rst = 0; |
| lane_rst.s.l1_rst = 0; |
| csr_wr(CVMX_GSERX_SATA_LANE_RST(qlm), lane_rst.u64); |
| csr_rd(CVMX_GSERX_SATA_LANE_RST(qlm)); |
| |
| udelay(1); |
| |
| /* |
| * 4. Take the PHY out of reset |
| * Write GSERX_PHY_CTL.PHY_RESET to a zero |
| */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| /* PCIe mode doesn't become ready until the PEM block attempts to bring |
| * the interface up. Skip this check for PCIe |
| */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_QLM_STAT(qlm), cvmx_gserx_qlm_stat_t, |
| rst_rdy, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", qlm); |
| return -1; |
| } |
| |
| /* Workaround for errata GSER-30310: SATA HDD Not Ready due to |
| * PHY SDLL/LDLL lockup at 3GHz |
| */ |
| for (i = 0; i < 2; i++) { |
| cvmx_gserx_slicex_pcie1_mode_t pcie1; |
| cvmx_gserx_slicex_pcie2_mode_t pcie2; |
| cvmx_gserx_slicex_pcie3_mode_t pcie3; |
| |
| pcie1.u64 = csr_rd(CVMX_GSERX_SLICEX_PCIE1_MODE(i, qlm)); |
| pcie1.s.rx_pi_bwsel = 1; |
| pcie1.s.rx_ldll_bwsel = 1; |
| pcie1.s.rx_sdll_bwsel = 1; |
| csr_wr(CVMX_GSERX_SLICEX_PCIE1_MODE(i, qlm), pcie1.u64); |
| |
| pcie2.u64 = csr_rd(CVMX_GSERX_SLICEX_PCIE2_MODE(i, qlm)); |
| pcie2.s.rx_pi_bwsel = 1; |
| pcie2.s.rx_ldll_bwsel = 1; |
| pcie2.s.rx_sdll_bwsel = 1; |
| csr_wr(CVMX_GSERX_SLICEX_PCIE2_MODE(i, qlm), pcie2.u64); |
| |
| pcie3.u64 = csr_rd(CVMX_GSERX_SLICEX_PCIE3_MODE(i, qlm)); |
| pcie3.s.rx_pi_bwsel = 1; |
| pcie3.s.rx_ldll_bwsel = 1; |
| pcie3.s.rx_sdll_bwsel = 1; |
| csr_wr(CVMX_GSERX_SLICEX_PCIE3_MODE(i, qlm), pcie3.u64); |
| } |
| |
| /* |
| * 7. Change P2 termination |
| * Clear GSERX_RX_PWR_CTRL_P2.P2_RX_SUBBLK_PD[0] (Termination) |
| */ |
| pwr_ctrl_p2.u64 = csr_rd(CVMX_GSERX_RX_PWR_CTRL_P2(qlm)); |
| pwr_ctrl_p2.s.p2_rx_subblk_pd &= 0x1e; |
| csr_wr(CVMX_GSERX_RX_PWR_CTRL_P2(qlm), pwr_ctrl_p2.u64); |
| |
| /* |
| * 8. Modify the Electrical IDLE Detect on delay |
| * Change GSERX_LANE(0..3)_MISC_CFG_0.EIE_DET_STL_ON_TIME to a 0x4 |
| */ |
| for (i = 0; i < 2; i++) { |
| misc_cfg_0.u64 = csr_rd(CVMX_GSERX_LANEX_MISC_CFG_0(i, qlm)); |
| misc_cfg_0.s.eie_det_stl_on_time = 4; |
| csr_wr(CVMX_GSERX_LANEX_MISC_CFG_0(i, qlm), misc_cfg_0.u64); |
| } |
| |
| /* |
| * 9. Modify the PLL and Lane Protocol Mode registers to configure |
| * the PHY for SATA. |
| * (Configure all 3 PLLs, doesn't matter what speed it is configured) |
| */ |
| |
| /* Errata (GSER-26724) SATA never indicates GSER QLM_STAT[RST_RDY] |
| * We program PLL_PX_MODE_0 last due to this errata |
| */ |
| for (l = 0; l < 3; l++) { |
| pmode_1.u64 = csr_rd(CVMX_GSERX_PLL_PX_MODE_1(l, qlm)); |
| lane_pmode_0.u64 = csr_rd(CVMX_GSERX_LANE_PX_MODE_0(l, qlm)); |
| lane_pmode_1.u64 = csr_rd(CVMX_GSERX_LANE_PX_MODE_1(l, qlm)); |
| |
| pmode_1.s.pll_cpadj = 0x2; |
| pmode_1.s.pll_opr = 0x0; |
| pmode_1.s.pll_div = 0x1e; |
| pmode_1.s.pll_pcie3en = 0x0; |
| pmode_1.s.pll_16p5en = 0x0; |
| |
| lane_pmode_0.s.ctle = 0x0; |
| lane_pmode_0.s.pcie = 0x0; |
| lane_pmode_0.s.tx_ldiv = 0x0; |
| lane_pmode_0.s.srate = 0; |
| lane_pmode_0.s.tx_mode = 0x3; |
| lane_pmode_0.s.rx_mode = 0x3; |
| |
| lane_pmode_1.s.vma_mm = 1; |
| lane_pmode_1.s.vma_fine_cfg_sel = 0; |
| lane_pmode_1.s.cdr_fgain = 0xa; |
| lane_pmode_1.s.ph_acc_adj = 0x15; |
| |
| if (l == R_2_5G_REFCLK100) |
| lane_pmode_0.s.rx_ldiv = 0x2; |
| else if (l == R_5G_REFCLK100) |
| lane_pmode_0.s.rx_ldiv = 0x1; |
| else |
| lane_pmode_0.s.rx_ldiv = 0x0; |
| |
| csr_wr(CVMX_GSERX_PLL_PX_MODE_1(l, qlm), pmode_1.u64); |
| csr_wr(CVMX_GSERX_LANE_PX_MODE_0(l, qlm), lane_pmode_0.u64); |
| csr_wr(CVMX_GSERX_LANE_PX_MODE_1(l, qlm), lane_pmode_1.u64); |
| } |
| |
| for (l = 0; l < 3; l++) { |
| pmode_0.u64 = csr_rd(CVMX_GSERX_PLL_PX_MODE_0(l, qlm)); |
| pmode_0.s.pll_icp = 0x1; |
| pmode_0.s.pll_rloop = 0x3; |
| pmode_0.s.pll_pcs_div = 0x5; |
| csr_wr(CVMX_GSERX_PLL_PX_MODE_0(l, qlm), pmode_0.u64); |
| } |
| |
| for (i = 0; i < 2; i++) { |
| cvmx_gserx_slicex_rx_sdll_ctrl_t rx_sdll; |
| |
| rx_sdll.u64 = csr_rd(CVMX_GSERX_SLICEX_RX_SDLL_CTRL(i, qlm)); |
| rx_sdll.s.pcs_sds_oob_clk_ctrl = 2; |
| rx_sdll.s.pcs_sds_rx_sdll_tune = 0; |
| rx_sdll.s.pcs_sds_rx_sdll_swsel = 0; |
| csr_wr(CVMX_GSERX_SLICEX_RX_SDLL_CTRL(i, qlm), rx_sdll.u64); |
| } |
| |
| for (i = 0; i < 2; i++) { |
| cvmx_gserx_lanex_misc_cfg_0_t misc_cfg; |
| |
| misc_cfg.u64 = csr_rd(CVMX_GSERX_LANEX_MISC_CFG_0(i, qlm)); |
| misc_cfg.s.use_pma_polarity = 0; |
| misc_cfg.s.cfg_pcs_loopback = 0; |
| misc_cfg.s.pcs_tx_mode_ovrrd_en = 0; |
| misc_cfg.s.pcs_rx_mode_ovrrd_en = 0; |
| misc_cfg.s.cfg_eie_det_cnt = 0; |
| misc_cfg.s.eie_det_stl_on_time = 4; |
| misc_cfg.s.eie_det_stl_off_time = 0; |
| misc_cfg.s.tx_bit_order = 1; |
| misc_cfg.s.rx_bit_order = 1; |
| csr_wr(CVMX_GSERX_LANEX_MISC_CFG_0(i, qlm), misc_cfg.u64); |
| } |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| /* PCIe mode doesn't become ready until the PEM block attempts to bring |
| * the interface up. Skip this check for PCIe |
| */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_QLM_STAT(qlm), cvmx_gserx_qlm_stat_t, |
| rst_rdy, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", qlm); |
| return -1; |
| } |
| |
| /* Poll GSERX_SATA_STATUS for P0_RDY = 1 */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_SATA_STATUS(qlm), cvmx_gserx_sata_status_t, |
| p0_rdy, ==, 1, 10000)) { |
| printf("QLM4: Timeout waiting for GSERX_SATA_STATUS[p0_rdy]\n"); |
| return -1; |
| } |
| |
| /* Poll GSERX_SATA_STATUS for P1_RDY = 1 */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_SATA_STATUS(qlm), cvmx_gserx_sata_status_t, |
| p1_rdy, ==, 1, 10000)) { |
| printf("QLM4: Timeout waiting for GSERX_SATA_STATUS[p1_rdy]\n"); |
| return -1; |
| } |
| |
| udelay(2000); |
| |
| /* 6. Deassert UCTL and UAHC resets: |
| * a. SATA_UCTL_CTL[UCTL_RST] = 0 |
| * b. SATA_UCTL_CTL[UAHC_RST] = 0 |
| * c. Wait 10 ACLK cycles before accessing any ACLK-only registers. |
| */ |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.sata_uctl_rst = 0; |
| uctl_ctl.s.sata_uahc_rst = 0; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| udelay(1); |
| |
| /* 7. Enable conditional SCLK of UCTL by writing |
| * SATA_UCTL_CTL[CSCLK_EN] = 1 |
| */ |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.csclk_en = 1; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| /* set-up endian mode */ |
| shim_cfg.u64 = csr_rd(CVMX_SATA_UCTL_SHIM_CFG); |
| shim_cfg.s.dma_endian_mode = 1; |
| shim_cfg.s.csr_endian_mode = 3; |
| csr_wr(CVMX_SATA_UCTL_SHIM_CFG, shim_cfg.u64); |
| |
| return 0; |
| } |
| |
| static int __dlm2_sata_uahc_init_cn70xx(int baud_mhz) |
| { |
| cvmx_sata_uahc_gbl_cap_t gbl_cap; |
| cvmx_sata_uahc_px_sctl_t sctl; |
| cvmx_sata_uahc_gbl_pi_t pi; |
| cvmx_sata_uahc_px_cmd_t cmd; |
| cvmx_sata_uahc_px_sctl_t sctl0, sctl1; |
| cvmx_sata_uahc_px_ssts_t ssts; |
| cvmx_sata_uahc_px_tfd_t tfd; |
| cvmx_sata_uahc_gbl_timer1ms_t gbl_timer1ms; |
| u64 done; |
| int result = -1; |
| int retry_count = 0; |
| int spd; |
| |
| /* From the synopsis data book, SATA_UAHC_GBL_TIMER1MS is the |
| * AMBA clock in MHz * 1000, which is a_clk(Hz) / 1000 |
| */ |
| gbl_timer1ms.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_TIMER1MS); |
| gbl_timer1ms.s.timv = a_clk / 1000; |
| csr_wr32(CVMX_SATA_UAHC_GBL_TIMER1MS, gbl_timer1ms.u32); |
| gbl_timer1ms.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_TIMER1MS); |
| |
| /* Set-u global capabilities reg (GBL_CAP) */ |
| gbl_cap.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_CAP); |
| debug("%s: SATA_UAHC_GBL_CAP before: 0x%x\n", __func__, gbl_cap.u32); |
| gbl_cap.s.sss = 1; |
| gbl_cap.s.smps = 1; |
| csr_wr32(CVMX_SATA_UAHC_GBL_CAP, gbl_cap.u32); |
| gbl_cap.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_CAP); |
| debug("%s: SATA_UAHC_GBL_CAP after: 0x%x\n", __func__, gbl_cap.u32); |
| |
| /* Set-up global hba control reg (interrupt enables) */ |
| /* Set-up port SATA control registers (speed limitation) */ |
| if (baud_mhz == 1500) |
| spd = 1; |
| else if (baud_mhz == 3000) |
| spd = 2; |
| else |
| spd = 3; |
| |
| sctl.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(0)); |
| debug("%s: SATA_UAHC_P0_SCTL before: 0x%x\n", __func__, sctl.u32); |
| sctl.s.spd = spd; |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(0), sctl.u32); |
| sctl.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(0)); |
| debug("%s: SATA_UAHC_P0_SCTL after: 0x%x\n", __func__, sctl.u32); |
| sctl.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(1)); |
| debug("%s: SATA_UAHC_P1_SCTL before: 0x%x\n", __func__, sctl.u32); |
| sctl.s.spd = spd; |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(1), sctl.u32); |
| sctl.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(1)); |
| debug("%s: SATA_UAHC_P1_SCTL after: 0x%x\n", __func__, sctl.u32); |
| |
| /* Set-up ports implemented reg. */ |
| pi.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_PI); |
| debug("%s: SATA_UAHC_GBL_PI before: 0x%x\n", __func__, pi.u32); |
| pi.s.pi = 3; |
| csr_wr32(CVMX_SATA_UAHC_GBL_PI, pi.u32); |
| pi.u32 = csr_rd32(CVMX_SATA_UAHC_GBL_PI); |
| debug("%s: SATA_UAHC_GBL_PI after: 0x%x\n", __func__, pi.u32); |
| |
| retry0: |
| /* Clear port SERR and IS registers */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SERR(0), csr_rd32(CVMX_SATA_UAHC_PX_SERR(0))); |
| csr_wr32(CVMX_SATA_UAHC_PX_IS(0), csr_rd32(CVMX_SATA_UAHC_PX_IS(0))); |
| |
| /* Set spin-up, power on, FIS RX enable, start, active */ |
| cmd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_CMD(0)); |
| debug("%s: SATA_UAHC_P0_CMD before: 0x%x\n", __func__, cmd.u32); |
| cmd.s.fre = 1; |
| cmd.s.sud = 1; |
| cmd.s.pod = 1; |
| cmd.s.st = 1; |
| cmd.s.icc = 1; |
| cmd.s.fbscp = 1; /* Enable FIS-based switching */ |
| csr_wr32(CVMX_SATA_UAHC_PX_CMD(0), cmd.u32); |
| cmd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_CMD(0)); |
| debug("%s: SATA_UAHC_P0_CMD after: 0x%x\n", __func__, cmd.u32); |
| |
| sctl0.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(0)); |
| sctl0.s.det = 1; |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(0), sctl0.u32); |
| |
| /* check status */ |
| done = get_timer(0); |
| while (1) { |
| ssts.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SSTS(0)); |
| |
| if (ssts.s.ipm == 1 && ssts.s.det == 3) { |
| result = 0; |
| break; |
| } else if (get_timer(done) > 100) { |
| result = -1; |
| break; |
| } |
| |
| udelay(100); |
| } |
| |
| if (result != -1) { |
| /* Clear the PxSERR Register, by writing '1s' to each |
| * implemented bit location |
| */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SERR(0), -1); |
| |
| /* |
| * Wait for indication that SATA drive is ready. This is |
| * determined via an examination of PxTFD.STS. If PxTFD.STS.BSY |
| * PxTFD.STS.DRQ, and PxTFD.STS.ERR are all '0', prior to the |
| * maximum allowed time as specified in the ATA/ATAPI-7 |
| * specification, the device is ready. |
| */ |
| /* |
| * Wait for the device to be ready. BSY(7), DRQ(3), and ERR(0) |
| * must be clear |
| */ |
| done = get_timer(0); |
| while (1) { |
| tfd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_TFD(0)); |
| if ((tfd.s.sts & 0x89) == 0) { |
| result = 0; |
| break; |
| } else if (get_timer(done) > 500) { |
| if (retry_count < 3) { |
| sctl0.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(0)); |
| sctl0.s.det = 1; /* Perform interface reset */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(0), sctl0.u32); |
| udelay(1000); /* 1ms dicated by AHCI 1.3 spec */ |
| sctl0.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(0)); |
| sctl0.s.det = 0; /* Perform interface reset */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(0), sctl0.u32); |
| retry_count++; |
| goto retry0; |
| } |
| result = -1; |
| break; |
| } |
| |
| udelay(100); |
| } |
| } |
| |
| if (result == -1) |
| printf("SATA0: not available\n"); |
| else |
| printf("SATA0: available\n"); |
| |
| sctl1.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(1)); |
| sctl1.s.det = 1; |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(1), sctl1.u32); |
| |
| result = -1; |
| retry_count = 0; |
| |
| retry1: |
| /* Clear port SERR and IS registers */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SERR(1), csr_rd32(CVMX_SATA_UAHC_PX_SERR(1))); |
| csr_wr32(CVMX_SATA_UAHC_PX_IS(1), csr_rd32(CVMX_SATA_UAHC_PX_IS(1))); |
| |
| /* Set spin-up, power on, FIS RX enable, start, active */ |
| cmd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_CMD(1)); |
| debug("%s: SATA_UAHC_P1_CMD before: 0x%x\n", __func__, cmd.u32); |
| cmd.s.fre = 1; |
| cmd.s.sud = 1; |
| cmd.s.pod = 1; |
| cmd.s.st = 1; |
| cmd.s.icc = 1; |
| cmd.s.fbscp = 1; /* Enable FIS-based switching */ |
| csr_wr32(CVMX_SATA_UAHC_PX_CMD(1), cmd.u32); |
| cmd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_CMD(1)); |
| debug("%s: SATA_UAHC_P1_CMD after: 0x%x\n", __func__, cmd.u32); |
| |
| /* check status */ |
| done = get_timer(0); |
| while (1) { |
| ssts.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SSTS(1)); |
| |
| if (ssts.s.ipm == 1 && ssts.s.det == 3) { |
| result = 0; |
| break; |
| } else if (get_timer(done) > 1000) { |
| result = -1; |
| break; |
| } |
| |
| udelay(100); |
| } |
| |
| if (result != -1) { |
| /* Clear the PxSERR Register, by writing '1s' to each |
| * implemented bit location |
| */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SERR(1), csr_rd32(CVMX_SATA_UAHC_PX_SERR(1))); |
| |
| /* |
| * Wait for indication that SATA drive is ready. This is |
| * determined via an examination of PxTFD.STS. If PxTFD.STS.BSY |
| * PxTFD.STS.DRQ, and PxTFD.STS.ERR are all '0', prior to the |
| * maximum allowed time as specified in the ATA/ATAPI-7 |
| * specification, the device is ready. |
| */ |
| /* |
| * Wait for the device to be ready. BSY(7), DRQ(3), and ERR(0) |
| * must be clear |
| */ |
| done = get_timer(0); |
| while (1) { |
| tfd.u32 = csr_rd32(CVMX_SATA_UAHC_PX_TFD(1)); |
| if ((tfd.s.sts & 0x89) == 0) { |
| result = 0; |
| break; |
| } else if (get_timer(done) > 500) { |
| if (retry_count < 3) { |
| sctl0.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(1)); |
| sctl0.s.det = 1; /* Perform interface reset */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(1), sctl0.u32); |
| udelay(1000); /* 1ms dicated by AHCI 1.3 spec */ |
| sctl0.u32 = csr_rd32(CVMX_SATA_UAHC_PX_SCTL(1)); |
| sctl0.s.det = 0; /* Perform interface reset */ |
| csr_wr32(CVMX_SATA_UAHC_PX_SCTL(1), sctl0.u32); |
| retry_count++; |
| goto retry1; |
| } |
| result = -1; |
| break; |
| } |
| |
| udelay(100); |
| } |
| } |
| |
| if (result == -1) |
| printf("SATA1: not available\n"); |
| else |
| printf("SATA1: available\n"); |
| |
| return 0; |
| } |
| |
| static int __sata_bist_cn70xx(int qlm, int baud_mhz, int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_sata_uctl_bist_status_t bist_status; |
| cvmx_sata_uctl_ctl_t uctl_ctl; |
| cvmx_sata_uctl_shim_cfg_t shim_cfg; |
| u64 done; |
| int result = -1; |
| |
| debug("%s(%d, %d, %d, %d)\n", __func__, qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| bist_status.u64 = csr_rd(CVMX_SATA_UCTL_BIST_STATUS); |
| |
| { |
| if (__dlm2_sata_uctl_init_cn70xx()) { |
| printf("ERROR: Failed to initialize SATA UCTL CSRs\n"); |
| return -1; |
| } |
| if (OCTEON_IS_MODEL(OCTEON_CN73XX)) |
| result = __sata_dlm_init_cn73xx(qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| else |
| result = __sata_dlm_init_cn70xx(qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| if (result) { |
| printf("ERROR: Failed to initialize SATA GSER CSRs\n"); |
| return -1; |
| } |
| |
| uctl_ctl.u64 = csr_rd(CVMX_SATA_UCTL_CTL); |
| uctl_ctl.s.start_bist = 1; |
| csr_wr(CVMX_SATA_UCTL_CTL, uctl_ctl.u64); |
| |
| /* Set-up for a 1 sec timer. */ |
| done = get_timer(0); |
| while (1) { |
| bist_status.u64 = csr_rd(CVMX_SATA_UCTL_BIST_STATUS); |
| if ((bist_status.s.uctl_xm_r_bist_ndone | |
| bist_status.s.uctl_xm_w_bist_ndone | |
| bist_status.s.uahc_p0_rxram_bist_ndone | |
| bist_status.s.uahc_p1_rxram_bist_ndone | |
| bist_status.s.uahc_p0_txram_bist_ndone | |
| bist_status.s.uahc_p1_txram_bist_ndone) == 0) { |
| result = 0; |
| break; |
| } else if (get_timer(done) > 1000) { |
| result = -1; |
| break; |
| } |
| |
| udelay(100); |
| } |
| if (result == -1) { |
| printf("ERROR: SATA_UCTL_BIST_STATUS = 0x%llx\n", |
| (unsigned long long)bist_status.u64); |
| return -1; |
| } |
| |
| debug("%s: Initializing UAHC\n", __func__); |
| if (__dlm2_sata_uahc_init_cn70xx(baud_mhz)) { |
| printf("ERROR: Failed to initialize SATA UAHC CSRs\n"); |
| return -1; |
| } |
| } |
| |
| /* Change CSR_ENDIAN_MODE to big endian to use Open Source AHCI SATA |
| * driver |
| */ |
| shim_cfg.u64 = csr_rd(CVMX_SATA_UCTL_SHIM_CFG); |
| shim_cfg.s.csr_endian_mode = 1; |
| csr_wr(CVMX_SATA_UCTL_SHIM_CFG, shim_cfg.u64); |
| |
| return 0; |
| } |
| |
| static int __setup_sata(int qlm, int baud_mhz, int ref_clk_sel, int ref_clk_input) |
| { |
| debug("%s(%d, %d, %d, %d)\n", __func__, qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| return __sata_bist_cn70xx(qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| } |
| |
| static int __dlmx_setup_pcie_cn70xx(int qlm, enum cvmx_qlm_mode mode, int gen2, int rc, |
| int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_gserx_dlmx_phy_reset_t dlmx_phy_reset; |
| cvmx_gserx_dlmx_test_powerdown_t dlmx_test_powerdown; |
| cvmx_gserx_dlmx_mpll_multiplier_t mpll_multiplier; |
| cvmx_gserx_dlmx_ref_clkdiv2_t ref_clkdiv2; |
| static const u8 ref_clk_mult[2] = { 35, 56 }; /* 100 & 125 MHz ref clock supported. */ |
| |
| debug("%s(%d, %d, %d, %d, %d, %d)\n", __func__, qlm, mode, gen2, rc, ref_clk_sel, |
| ref_clk_input); |
| if (rc == 0) { |
| debug("Skipping initializing PCIe dlm %d in endpoint mode\n", qlm); |
| return 0; |
| } |
| |
| if (qlm > 0 && ref_clk_input > 1) { |
| printf("%s: Error: ref_clk_input can only be 0 or 1 for QLM %d\n", |
| __func__, qlm); |
| return -1; |
| } |
| |
| if (ref_clk_sel > OCTEON_QLM_REF_CLK_125MHZ) { |
| printf("%s: Error: ref_clk_sel can only be 100 or 125 MHZ.\n", __func__); |
| return -1; |
| } |
| |
| /* 1. Write GSER0_DLM(1..2)_REFCLK_SEL[REFCLK_SEL] if required for |
| * reference-clock selection |
| */ |
| |
| csr_wr(CVMX_GSERX_DLMX_REFCLK_SEL(qlm, 0), ref_clk_input); |
| |
| /* 2. If required, write GSER0_DLM(1..2)_REF_CLKDIV2[REF_CLKDIV2] = 1 |
| * (must be set if reference clock >= 100 MHz) |
| */ |
| |
| /* 4. Configure the PCIE PIPE: |
| * a. Write GSER0_PCIE_PIPE_PORT_SEL[PIPE_PORT_SEL] to configure the |
| * PCIE PIPE. |
| * 0x0 = disables all pipes |
| * 0x1 = enables pipe0 only (PEM0 4-lane) |
| * 0x2 = enables pipes 0 and 1 (PEM0 and PEM1 2-lanes each) |
| * 0x3 = enables pipes 0, 1, 2, and 3 (PEM0, PEM1, and PEM3 are |
| * one-lane each) |
| * b. Configure GSER0_PCIE_PIPE_PORT_SEL[CFG_PEM1_DLM2]. If PEM1 is |
| * to be configured, this bit must reflect which DLM it is logically |
| * tied to. This bit sets multiplexing logic in GSER, and it is used |
| * by the RST logic to determine when the MAC can come out of reset. |
| * 0 = PEM1 is tied to DLM1 (for 3 x 1 PCIe mode). |
| * 1 = PEM1 is tied to DLM2 (for all other PCIe modes). |
| */ |
| if (qlm == 1) { |
| cvmx_gserx_pcie_pipe_port_sel_t pipe_port; |
| |
| pipe_port.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_PORT_SEL(0)); |
| pipe_port.s.cfg_pem1_dlm2 = (mode == CVMX_QLM_MODE_PCIE_1X1) ? 1 : 0; |
| pipe_port.s.pipe_port_sel = |
| (mode == CVMX_QLM_MODE_PCIE) ? 1 : /* PEM0 only */ |
| (mode == CVMX_QLM_MODE_PCIE_1X2) ? 2 : /* PEM0-1 */ |
| (mode == CVMX_QLM_MODE_PCIE_1X1) ? 3 : /* PEM0-2 */ |
| (mode == CVMX_QLM_MODE_PCIE_2X1) ? 3 : /* PEM0-1 */ |
| 0; /* PCIe disabled */ |
| csr_wr(CVMX_GSERX_PCIE_PIPE_PORT_SEL(0), pipe_port.u64); |
| } |
| |
| /* Apply workaround for Errata (G-20669) MPLL may not come up. */ |
| |
| /* Set REF_CLKDIV2 based on the Ref Clock */ |
| ref_clkdiv2.u64 = csr_rd(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0)); |
| ref_clkdiv2.s.ref_clkdiv2 = ref_clk_sel > 0; |
| csr_wr(CVMX_GSERX_DLMX_REF_CLKDIV2(qlm, 0), ref_clkdiv2.u64); |
| |
| /* 1. Ensure GSER(0)_DLM(0..2)_PHY_RESET[PHY_RESET] is set. */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 2. If SGMII or QSGMII or RXAUI (i.e. if DLM0) set |
| * GSER(0)_DLM(0)_MPLL_EN[MPLL_EN] to one. |
| */ |
| |
| /* 3. Set GSER(0)_DLM(0..2)_MPLL_MULTIPLIER[MPLL_MULTIPLIER] |
| * to the value in the preceding table, which is different |
| * than the desired setting prescribed by the HRM. |
| */ |
| mpll_multiplier.u64 = csr_rd(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0)); |
| mpll_multiplier.s.mpll_multiplier = ref_clk_mult[ref_clk_sel]; |
| debug("%s: Setting MPLL multiplier to %d\n", __func__, |
| (int)mpll_multiplier.s.mpll_multiplier); |
| csr_wr(CVMX_GSERX_DLMX_MPLL_MULTIPLIER(qlm, 0), mpll_multiplier.u64); |
| /* 5. Clear GSER0_DLM(1..2)_TEST_POWERDOWN. Configurations that only |
| * use DLM1 need not clear GSER0_DLM2_TEST_POWERDOWN |
| */ |
| dlmx_test_powerdown.u64 = csr_rd(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0)); |
| dlmx_test_powerdown.s.test_powerdown = 0; |
| csr_wr(CVMX_GSERX_DLMX_TEST_POWERDOWN(qlm, 0), dlmx_test_powerdown.u64); |
| |
| /* 6. Clear GSER0_DLM(1..2)_PHY_RESET. Configurations that use only |
| * need DLM1 need not clear GSER0_DLM2_PHY_RESET |
| */ |
| dlmx_phy_reset.u64 = csr_rd(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0)); |
| dlmx_phy_reset.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_DLMX_PHY_RESET(qlm, 0), dlmx_phy_reset.u64); |
| |
| /* 6. Decrease MPLL_MULTIPLIER by one continually until it reaches |
| * the desired long-term setting, ensuring that each MPLL_MULTIPLIER |
| * value is constant for at least 1 msec before changing to the next |
| * value. The desired long-term setting is as indicated in HRM tables |
| * 21-1, 21-2, and 21-3. This is not required with the HRM |
| * sequence. |
| */ |
| /* This is set when initializing PCIe after soft reset is asserted. */ |
| |
| /* 7. Write the GSER0_PCIE_PIPE_RST register to take the appropriate |
| * PIPE out of reset. There is a PIPEn_RST bit for each PIPE. Clear |
| * the appropriate bits based on the configuration (reset is |
| * active high). |
| */ |
| if (qlm == 1) { |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| cvmx_gserx_pcie_pipe_rst_t pipe_rst; |
| cvmx_rst_ctlx_t rst_ctl; |
| |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE: /* PEM0 on DLM1 & DLM2 */ |
| case CVMX_QLM_MODE_PCIE_1X2: /* PEM0 on DLM1 */ |
| case CVMX_QLM_MODE_PCIE_1X1: /* PEM0 on DLM1 using lane 0 */ |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(0)); |
| pemx_cfg.cn70xx.hostmd = rc; |
| if (mode == CVMX_QLM_MODE_PCIE_1X1) { |
| pemx_cfg.cn70xx.md = |
| gen2 ? CVMX_PEM_MD_GEN2_1LANE : CVMX_PEM_MD_GEN1_1LANE; |
| } else if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_cfg.cn70xx.md = |
| gen2 ? CVMX_PEM_MD_GEN2_4LANE : CVMX_PEM_MD_GEN1_4LANE; |
| } else { |
| pemx_cfg.cn70xx.md = |
| gen2 ? CVMX_PEM_MD_GEN2_2LANE : CVMX_PEM_MD_GEN1_2LANE; |
| } |
| csr_wr(CVMX_PEMX_CFG(0), pemx_cfg.u64); |
| |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(0)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(0), rst_ctl.u64); |
| |
| /* PEM0 is on DLM1&2 which is pipe0 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe0_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| break; |
| case CVMX_QLM_MODE_PCIE_2X1: /* PEM0 and PEM1 on DLM1 */ |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(0)); |
| pemx_cfg.cn70xx.hostmd = rc; |
| pemx_cfg.cn70xx.md = gen2 ? CVMX_PEM_MD_GEN2_1LANE : CVMX_PEM_MD_GEN1_1LANE; |
| csr_wr(CVMX_PEMX_CFG(0), pemx_cfg.u64); |
| |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(0)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(0), rst_ctl.u64); |
| |
| /* PEM0 is on DLM1 which is pipe0 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe0_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(1)); |
| pemx_cfg.cn70xx.hostmd = 1; |
| pemx_cfg.cn70xx.md = gen2 ? CVMX_PEM_MD_GEN2_1LANE : CVMX_PEM_MD_GEN1_1LANE; |
| csr_wr(CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(1)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(1), rst_ctl.u64); |
| /* PEM1 is on DLM2 which is pipe1 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe1_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(1), pemx_on.u64); |
| break; |
| default: |
| break; |
| } |
| } else { |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| cvmx_gserx_pcie_pipe_rst_t pipe_rst; |
| cvmx_rst_ctlx_t rst_ctl; |
| |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE_1X2: /* PEM1 on DLM2 */ |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(1)); |
| pemx_cfg.cn70xx.hostmd = 1; |
| pemx_cfg.cn70xx.md = gen2 ? CVMX_PEM_MD_GEN2_2LANE : CVMX_PEM_MD_GEN1_2LANE; |
| csr_wr(CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(1)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(1), rst_ctl.u64); |
| |
| /* PEM1 is on DLM1 lane 0, which is pipe1 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe1_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(1), pemx_on.u64); |
| break; |
| case CVMX_QLM_MODE_PCIE_2X1: /* PEM1 and PEM2 on DLM2 */ |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(1)); |
| pemx_cfg.cn70xx.hostmd = 1; |
| pemx_cfg.cn70xx.md = gen2 ? CVMX_PEM_MD_GEN2_1LANE : CVMX_PEM_MD_GEN1_1LANE; |
| csr_wr(CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(1)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(1), rst_ctl.u64); |
| |
| /* PEM1 is on DLM2 lane 0, which is pipe2 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe2_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(1), pemx_on.u64); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(2)); |
| pemx_cfg.cn70xx.hostmd = 1; |
| pemx_cfg.cn70xx.md = gen2 ? CVMX_PEM_MD_GEN2_1LANE : CVMX_PEM_MD_GEN1_1LANE; |
| csr_wr(CVMX_PEMX_CFG(2), pemx_cfg.u64); |
| |
| rst_ctl.u64 = csr_rd(CVMX_RST_CTLX(2)); |
| rst_ctl.s.rst_drv = 1; |
| csr_wr(CVMX_RST_CTLX(2), rst_ctl.u64); |
| |
| /* PEM2 is on DLM2 lane 1, which is pipe3 */ |
| pipe_rst.u64 = csr_rd(CVMX_GSERX_PCIE_PIPE_RST(0)); |
| pipe_rst.s.pipe3_rst = 0; |
| csr_wr(CVMX_GSERX_PCIE_PIPE_RST(0), pipe_rst.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(2)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(2), pemx_on.u64); |
| break; |
| default: |
| break; |
| } |
| } |
| return 0; |
| } |
| |
| /** |
| * Configure dlm speed and mode for cn70xx. |
| * |
| * @param qlm The DLM to configure |
| * @param speed The speed the DLM needs to be configured in Mhz. |
| * @param mode The DLM to be configured as SGMII/XAUI/PCIe. |
| * DLM 0: has 2 interfaces which can be configured as |
| * SGMII/QSGMII/RXAUI. Need to configure both at the |
| * same time. These are valid option |
| * CVMX_QLM_MODE_QSGMII, |
| * CVMX_QLM_MODE_SGMII_SGMII, |
| * CVMX_QLM_MODE_SGMII_DISABLED, |
| * CVMX_QLM_MODE_DISABLED_SGMII, |
| * CVMX_QLM_MODE_SGMII_QSGMII, |
| * CVMX_QLM_MODE_QSGMII_QSGMII, |
| * CVMX_QLM_MODE_QSGMII_DISABLED, |
| * CVMX_QLM_MODE_DISABLED_QSGMII, |
| * CVMX_QLM_MODE_QSGMII_SGMII, |
| * CVMX_QLM_MODE_RXAUI_1X2 |
| * |
| * DLM 1: PEM0/1 in PCIE_1x4/PCIE_2x1/PCIE_1X1 |
| * DLM 2: PEM0/1/2 in PCIE_1x4/PCIE_1x2/PCIE_2x1/PCIE_1x1 |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP mode. |
| * @param gen2 Only used for PCIe, gen2 = 1, in GEN2 mode else in GEN1 mode. |
| * |
| * @param ref_clk_input The reference-clock input to use to configure QLM |
| * @param ref_clk_sel The reference-clock selection to use to configure QLM |
| * |
| * @return Return 0 on success or -1. |
| */ |
| static int octeon_configure_qlm_cn70xx(int qlm, int speed, int mode, int rc, int gen2, |
| int ref_clk_sel, int ref_clk_input) |
| { |
| debug("%s(%d, %d, %d, %d, %d, %d, %d)\n", __func__, qlm, speed, mode, rc, gen2, ref_clk_sel, |
| ref_clk_input); |
| switch (qlm) { |
| case 0: { |
| int is_sff7000_rxaui = 0; |
| cvmx_gmxx_inf_mode_t inf_mode0, inf_mode1; |
| |
| inf_mode0.u64 = csr_rd(CVMX_GMXX_INF_MODE(0)); |
| inf_mode1.u64 = csr_rd(CVMX_GMXX_INF_MODE(1)); |
| if (inf_mode0.s.en || inf_mode1.s.en) { |
| debug("DLM0 already configured\n"); |
| return -1; |
| } |
| |
| switch (mode) { |
| case CVMX_QLM_MODE_SGMII_SGMII: |
| debug(" Mode SGMII SGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| break; |
| case CVMX_QLM_MODE_SGMII_QSGMII: |
| debug(" Mode SGMII QSGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| break; |
| case CVMX_QLM_MODE_SGMII_DISABLED: |
| debug(" Mode SGMII Disabled\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| break; |
| case CVMX_QLM_MODE_DISABLED_SGMII: |
| debug("Mode Disabled SGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| break; |
| case CVMX_QLM_MODE_QSGMII_SGMII: |
| debug(" Mode QSGMII SGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_SGMII; |
| break; |
| case CVMX_QLM_MODE_QSGMII_QSGMII: |
| debug(" Mode QSGMII QSGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| break; |
| case CVMX_QLM_MODE_QSGMII_DISABLED: |
| debug(" Mode QSGMII Disabled\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| break; |
| case CVMX_QLM_MODE_DISABLED_QSGMII: |
| debug("Mode Disabled QSGMII\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_QSGMII; |
| break; |
| case CVMX_QLM_MODE_RXAUI: |
| debug(" Mode RXAUI\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_RXAUI; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| |
| break; |
| default: |
| debug(" Mode Disabled Disabled\n"); |
| inf_mode0.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| inf_mode1.s.mode = CVMX_GMX_INF_MODE_DISABLED; |
| break; |
| } |
| csr_wr(CVMX_GMXX_INF_MODE(0), inf_mode0.u64); |
| csr_wr(CVMX_GMXX_INF_MODE(1), inf_mode1.u64); |
| |
| /* Bringup the PLL */ |
| if (__dlm_setup_pll_cn70xx(qlm, speed, ref_clk_sel, ref_clk_input, |
| is_sff7000_rxaui)) |
| return -1; |
| |
| /* TX Lanes */ |
| if (__dlm0_setup_tx_cn70xx(speed, ref_clk_sel)) |
| return -1; |
| |
| /* RX Lanes */ |
| if (__dlm0_setup_rx_cn70xx(speed, ref_clk_sel)) |
| return -1; |
| |
| /* Enable the interface */ |
| inf_mode0.u64 = csr_rd(CVMX_GMXX_INF_MODE(0)); |
| if (inf_mode0.s.mode != CVMX_GMX_INF_MODE_DISABLED) |
| inf_mode0.s.en = 1; |
| csr_wr(CVMX_GMXX_INF_MODE(0), inf_mode0.u64); |
| inf_mode1.u64 = csr_rd(CVMX_GMXX_INF_MODE(1)); |
| if (inf_mode1.s.mode != CVMX_GMX_INF_MODE_DISABLED) |
| inf_mode1.s.en = 1; |
| csr_wr(CVMX_GMXX_INF_MODE(1), inf_mode1.u64); |
| break; |
| } |
| case 1: |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE: /* PEM0 on DLM1 & DLM2 */ |
| debug(" Mode PCIe\n"); |
| if (__dlmx_setup_pcie_cn70xx(1, mode, gen2, rc, ref_clk_sel, ref_clk_input)) |
| return -1; |
| if (__dlmx_setup_pcie_cn70xx(2, mode, gen2, rc, ref_clk_sel, ref_clk_input)) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_PCIE_1X2: /* PEM0 on DLM1 */ |
| case CVMX_QLM_MODE_PCIE_2X1: /* PEM0 & PEM1 on DLM1 */ |
| case CVMX_QLM_MODE_PCIE_1X1: /* PEM0 on DLM1, only 1 lane */ |
| debug(" Mode PCIe 1x2, 2x1 or 1x1\n"); |
| if (__dlmx_setup_pcie_cn70xx(qlm, mode, gen2, rc, ref_clk_sel, |
| ref_clk_input)) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_DISABLED: |
| debug(" Mode disabled\n"); |
| break; |
| default: |
| debug("DLM1 illegal mode specified\n"); |
| return -1; |
| } |
| break; |
| case 2: |
| switch (mode) { |
| case CVMX_QLM_MODE_SATA_2X1: |
| debug("%s: qlm 2, mode is SATA 2x1\n", __func__); |
| /* DLM2 is SATA, PCIE2 is disabled */ |
| if (__setup_sata(qlm, speed, ref_clk_sel, ref_clk_input)) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_PCIE: |
| debug(" Mode PCIe\n"); |
| /* DLM2 is PCIE0, PCIE1-2 are disabled. */ |
| /* Do nothing, its initialized in DLM1 */ |
| break; |
| case CVMX_QLM_MODE_PCIE_1X2: /* PEM1 on DLM2 */ |
| case CVMX_QLM_MODE_PCIE_2X1: /* PEM1 & PEM2 on DLM2 */ |
| debug(" Mode PCIe 1x2 or 2x1\n"); |
| if (__dlmx_setup_pcie_cn70xx(qlm, mode, gen2, rc, ref_clk_sel, |
| ref_clk_input)) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_DISABLED: |
| debug(" Mode Disabled\n"); |
| break; |
| default: |
| debug("DLM2 illegal mode specified\n"); |
| return -1; |
| } |
| default: |
| return -1; |
| } |
| |
| return 0; |
| } |
| |
| /** |
| * Disables DFE for the specified QLM lane(s). |
| * This function should only be called for low-loss channels. |
| * |
| * @param node Node to configure |
| * @param qlm QLM to configure |
| * @param lane Lane to configure, or -1 all lanes |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| */ |
| void octeon_qlm_dfe_disable(int node, int qlm, int lane, int baud_mhz, int mode) |
| { |
| int num_lanes = cvmx_qlm_get_lanes(qlm); |
| int l; |
| cvmx_gserx_lanex_rx_loop_ctrl_t loop_ctrl; |
| cvmx_gserx_lanex_rx_valbbd_ctrl_0_t ctrl_0; |
| cvmx_gserx_lanex_rx_valbbd_ctrl_1_t ctrl_1; |
| cvmx_gserx_lanex_rx_valbbd_ctrl_2_t ctrl_2; |
| cvmx_gserx_lane_vma_fine_ctrl_2_t lane_vma_fine_ctrl_2; |
| |
| /* Interfaces below 5Gbaud are already manually tuned. */ |
| if (baud_mhz < 5000) |
| return; |
| |
| /* Don't run on PCIe links, SATA or KR. These interfaces use training */ |
| switch (mode) { |
| case CVMX_QLM_MODE_10G_KR_1X2: |
| case CVMX_QLM_MODE_10G_KR: |
| case CVMX_QLM_MODE_40G_KR4: |
| return; |
| case CVMX_QLM_MODE_PCIE_1X1: |
| case CVMX_QLM_MODE_PCIE_2X1: |
| case CVMX_QLM_MODE_PCIE_1X2: |
| case CVMX_QLM_MODE_PCIE: |
| case CVMX_QLM_MODE_PCIE_1X8: |
| return; |
| case CVMX_QLM_MODE_SATA_2X1: |
| return; |
| default: |
| break; |
| } |
| |
| /* Updating pre_ctle minimum to 0. This works best for short channels */ |
| lane_vma_fine_ctrl_2.u64 = csr_rd_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm)); |
| lane_vma_fine_ctrl_2.s.rx_prectle_gain_min_fine = 0; |
| csr_wr_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm), lane_vma_fine_ctrl_2.u64); |
| |
| for (l = 0; l < num_lanes; l++) { |
| if (lane != -1 && lane != l) |
| continue; |
| |
| /* 1. Write GSERX_LANEx_RX_LOOP_CTRL = 0x0270 |
| * (var "loop_ctrl" with bits 8 & 1 cleared). |
| * bit<1> dfe_en_byp = 1'b0 |
| */ |
| loop_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_LOOP_CTRL(l, qlm)); |
| loop_ctrl.s.cfg_rx_lctrl = loop_ctrl.s.cfg_rx_lctrl & 0x3fd; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_LOOP_CTRL(l, qlm), loop_ctrl.u64); |
| |
| /* 2. Write GSERX_LANEx_RX_VALBBD_CTRL_1 = 0x0000 |
| * (var "ctrl1" with all bits cleared) |
| * bits<14:11> CFG_RX_DFE_C3_MVAL = 4'b0000 |
| * bit<10> CFG_RX_DFE_C3_MSGN = 1'b0 |
| * bits<9:6> CFG_RX_DFE_C2_MVAL = 4'b0000 |
| * bit<5> CFG_RX_DFE_C2_MSGN = 1'b0 |
| * bits<4:0> CFG_RX_DFE_C1_MVAL = 5'b00000 |
| */ |
| ctrl_1.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_1(l, qlm)); |
| ctrl_1.s.dfe_c3_mval = 0; |
| ctrl_1.s.dfe_c3_msgn = 0; |
| ctrl_1.s.dfe_c2_mval = 0; |
| ctrl_1.s.dfe_c2_msgn = 0; |
| ctrl_1.s.dfe_c2_mval = 0; |
| ctrl_1.s.dfe_c1_mval = 0; |
| ctrl_1.s.dfe_c1_msgn = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_1(l, qlm), ctrl_1.u64); |
| |
| /* 3. Write GSERX_LANEx_RX_VALBBD_CTRL_0 = 0x2400 |
| * (var "ctrl0" with following bits set/cleared) |
| * bits<11:10> CFG_RX_DFE_GAIN = 0x1 |
| * bits<9:6> CFG_RX_DFE_C5_MVAL = 4'b0000 |
| * bit<5> CFG_RX_DFE_C5_MSGN = 1'b0 |
| * bits<4:1> CFG_RX_DFE_C4_MVAL = 4'b0000 |
| * bit<0> CFG_RX_DFE_C4_MSGN = 1'b0 |
| */ |
| ctrl_0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(l, qlm)); |
| ctrl_0.s.dfe_gain = 0x1; |
| ctrl_0.s.dfe_c5_mval = 0; |
| ctrl_0.s.dfe_c5_msgn = 0; |
| ctrl_0.s.dfe_c4_mval = 0; |
| ctrl_0.s.dfe_c4_msgn = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(l, qlm), ctrl_0.u64); |
| |
| /* 4. Write GSER(0..13)_LANE(0..3)_RX_VALBBD_CTRL_2 = 0x003F |
| * //enable DFE tap overrides |
| * bit<5> dfe_ovrd_en = 1 |
| * bit<4> dfe_c5_ovrd_val = 1 |
| * bit<3> dfe_c4_ovrd_val = 1 |
| * bit<2> dfe_c3_ovrd_val = 1 |
| * bit<1> dfe_c2_ovrd_val = 1 |
| * bit<0> dfe_c1_ovrd_val = 1 |
| */ |
| ctrl_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_2(l, qlm)); |
| ctrl_2.s.dfe_ovrd_en = 0x1; |
| ctrl_2.s.dfe_c5_ovrd_val = 0x1; |
| ctrl_2.s.dfe_c4_ovrd_val = 0x1; |
| ctrl_2.s.dfe_c3_ovrd_val = 0x1; |
| ctrl_2.s.dfe_c2_ovrd_val = 0x1; |
| ctrl_2.s.dfe_c1_ovrd_val = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_2(l, qlm), ctrl_2.u64); |
| } |
| } |
| |
| /** |
| * Disables DFE, uses fixed CTLE Peak value and AGC settings |
| * for the specified QLM lane(s). |
| * This function should only be called for low-loss channels. |
| * This function prevents Rx equalization from happening on all lanes in a QLM |
| * This function should be called for all lanes being used in the QLM. |
| * |
| * @param node Node to configure |
| * @param qlm QLM to configure |
| * @param lane Lane to configure, or -1 all lanes |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * @param ctle_zero Equalizer Peaking control |
| * @param agc_pre_ctle Pre-CTLE gain |
| * @param agc_post_ctle Post-CTLE gain |
| * @return Zero on success, negative on failure |
| */ |
| |
| int octeon_qlm_dfe_disable_ctle_agc(int node, int qlm, int lane, int baud_mhz, int mode, |
| int ctle_zero, int agc_pre_ctle, int agc_post_ctle) |
| { |
| int num_lanes = cvmx_qlm_get_lanes(qlm); |
| int l; |
| cvmx_gserx_lanex_rx_loop_ctrl_t loop_ctrl; |
| cvmx_gserx_lanex_rx_valbbd_ctrl_0_t ctrl_0; |
| cvmx_gserx_lanex_pwr_ctrl_t lanex_pwr_ctrl; |
| cvmx_gserx_lane_mode_t lmode; |
| cvmx_gserx_lane_px_mode_1_t px_mode_1; |
| cvmx_gserx_lanex_rx_cfg_5_t rx_cfg_5; |
| cvmx_gserx_lanex_rx_cfg_2_t rx_cfg_2; |
| cvmx_gserx_lanex_rx_ctle_ctrl_t ctle_ctrl; |
| |
| /* Check tuning constraints */ |
| if (ctle_zero < 0 || ctle_zero > 15) { |
| printf("Error: N%d.QLM%d: Invalid CTLE_ZERO(%d). Must be between -1 and 15.\n", |
| node, qlm, ctle_zero); |
| return -1; |
| } |
| if (agc_pre_ctle < 0 || agc_pre_ctle > 15) { |
| printf("Error: N%d.QLM%d: Invalid AGC_Pre_CTLE(%d)\n", |
| node, qlm, agc_pre_ctle); |
| return -1; |
| } |
| |
| if (agc_post_ctle < 0 || agc_post_ctle > 15) { |
| printf("Error: N%d.QLM%d: Invalid AGC_Post_CTLE(%d)\n", |
| node, qlm, agc_post_ctle); |
| return -1; |
| } |
| |
| /* Interfaces below 5Gbaud are already manually tuned. */ |
| if (baud_mhz < 5000) |
| return 0; |
| |
| /* Don't run on PCIe links, SATA or KR. These interfaces use training */ |
| switch (mode) { |
| case CVMX_QLM_MODE_10G_KR_1X2: |
| case CVMX_QLM_MODE_10G_KR: |
| case CVMX_QLM_MODE_40G_KR4: |
| return 0; |
| case CVMX_QLM_MODE_PCIE_1X1: |
| case CVMX_QLM_MODE_PCIE_2X1: |
| case CVMX_QLM_MODE_PCIE_1X2: |
| case CVMX_QLM_MODE_PCIE: |
| case CVMX_QLM_MODE_PCIE_1X8: |
| return 0; |
| case CVMX_QLM_MODE_SATA_2X1: |
| return 0; |
| default: |
| break; |
| } |
| |
| lmode.u64 = csr_rd_node(node, CVMX_GSERX_LANE_MODE(qlm)); |
| |
| /* 1. Enable VMA manual mode for the QLM's lane mode */ |
| px_mode_1.u64 = csr_rd_node(node, CVMX_GSERX_LANE_PX_MODE_1(lmode.s.lmode, qlm)); |
| px_mode_1.s.vma_mm = 1; |
| csr_wr_node(node, CVMX_GSERX_LANE_PX_MODE_1(lmode.s.lmode, qlm), px_mode_1.u64); |
| |
| /* 2. Disable DFE */ |
| octeon_qlm_dfe_disable(node, qlm, lane, baud_mhz, mode); |
| |
| for (l = 0; l < num_lanes; l++) { |
| if (lane != -1 && lane != l) |
| continue; |
| |
| /* 3. Write GSERX_LANEx_RX_VALBBD_CTRL_0.CFG_RX_AGC_GAIN = 0x2 */ |
| ctrl_0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(l, qlm)); |
| ctrl_0.s.agc_gain = 0x2; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(l, qlm), ctrl_0.u64); |
| |
| /* 4. Write GSERX_LANEx_RX_LOOP_CTRL |
| * bit<8> lctrl_men = 1'b1 |
| * bit<0> cdr_en_byp = 1'b1 |
| */ |
| loop_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_LOOP_CTRL(l, qlm)); |
| loop_ctrl.s.cfg_rx_lctrl = loop_ctrl.s.cfg_rx_lctrl | 0x101; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_LOOP_CTRL(l, qlm), loop_ctrl.u64); |
| |
| /* 5. Write GSERX_LANEx_PWR_CTRL = 0x0040 (var "lanex_pwr_ctrl" with |
| * following bits set) |
| * bit<6> RX_LCTRL_OVRRD_EN = 1'b1 |
| * all other bits cleared. |
| */ |
| lanex_pwr_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PWR_CTRL(l, qlm)); |
| lanex_pwr_ctrl.s.rx_lctrl_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PWR_CTRL(l, qlm), lanex_pwr_ctrl.u64); |
| |
| /* --Setting AGC in manual mode and configuring CTLE-- */ |
| rx_cfg_5.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_CFG_5(l, qlm)); |
| rx_cfg_5.s.rx_agc_men_ovrrd_val = 1; |
| rx_cfg_5.s.rx_agc_men_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_CFG_5(l, qlm), rx_cfg_5.u64); |
| |
| ctle_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_CTLE_CTRL(l, qlm)); |
| ctle_ctrl.s.pcs_sds_rx_ctle_zero = ctle_zero; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_CTLE_CTRL(l, qlm), ctle_ctrl.u64); |
| |
| rx_cfg_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_CFG_2(l, qlm)); |
| rx_cfg_2.s.rx_sds_rx_agc_mval = (agc_pre_ctle << 4) | agc_post_ctle; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_CFG_2(l, qlm), rx_cfg_2.u64); |
| } |
| return 0; |
| } |
| |
| /** |
| * Some QLM speeds need to override the default tuning parameters |
| * |
| * @param node Node to configure |
| * @param qlm QLM to configure |
| * @param baud_mhz Desired speed in MHz |
| * @param lane Lane the apply the tuning parameters |
| * @param tx_swing Voltage swing. The higher the value the lower the voltage, |
| * the default value is 7. |
| * @param tx_pre pre-cursor pre-emphasis |
| * @param tx_post post-cursor pre-emphasis. |
| * @param tx_gain Transmit gain. Range 0-7 |
| * @param tx_vboost Transmit voltage boost. Range 0-1 |
| */ |
| void octeon_qlm_tune_per_lane_v3(int node, int qlm, int baud_mhz, int lane, int tx_swing, |
| int tx_pre, int tx_post, int tx_gain, int tx_vboost) |
| { |
| cvmx_gserx_cfg_t gserx_cfg; |
| cvmx_gserx_lanex_tx_cfg_0_t tx_cfg0; |
| cvmx_gserx_lanex_tx_pre_emphasis_t pre_emphasis; |
| cvmx_gserx_lanex_tx_cfg_1_t tx_cfg1; |
| cvmx_gserx_lanex_tx_cfg_3_t tx_cfg3; |
| cvmx_bgxx_spux_br_pmd_control_t pmd_control; |
| cvmx_gserx_lanex_pcs_ctlifc_0_t pcs_ctlifc_0; |
| cvmx_gserx_lanex_pcs_ctlifc_2_t pcs_ctlifc_2; |
| int bgx, lmac; |
| |
| /* Do not apply QLM tuning to PCIe and KR interfaces. */ |
| gserx_cfg.u64 = csr_rd_node(node, CVMX_GSERX_CFG(qlm)); |
| if (gserx_cfg.s.pcie) |
| return; |
| |
| /* Apply the QLM tuning only to cn73xx and cn78xx models only */ |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX)) |
| bgx = (qlm < 2) ? qlm : (qlm - 2); |
| else if (OCTEON_IS_MODEL(OCTEON_CN73XX)) |
| bgx = (qlm < 4) ? (qlm - 2) : 2; |
| else if (OCTEON_IS_MODEL(OCTEON_CNF75XX)) |
| bgx = 0; |
| else |
| return; |
| |
| if ((OCTEON_IS_MODEL(OCTEON_CN73XX) && qlm == 6) || |
| (OCTEON_IS_MODEL(OCTEON_CNF75XX) && qlm == 5)) |
| lmac = 2; |
| else |
| lmac = lane; |
| |
| /* No need to tune 10G-KR and 40G-KR interfaces */ |
| pmd_control.u64 = csr_rd_node(node, CVMX_BGXX_SPUX_BR_PMD_CONTROL(lmac, bgx)); |
| if (pmd_control.s.train_en) |
| return; |
| |
| if (tx_pre != -1 && tx_post == -1) |
| tx_post = 0; |
| |
| if (tx_post != -1 && tx_pre == -1) |
| tx_pre = 0; |
| |
| /* Check tuning constraints */ |
| if (tx_swing < -1 || tx_swing > 25) { |
| printf("ERROR: N%d:QLM%d: Lane %d: Invalid TX_SWING(%d). TX_SWING must be <= 25.\n", |
| node, qlm, lane, tx_swing); |
| return; |
| } |
| |
| if (tx_pre < -1 || tx_pre > 10) { |
| printf("ERROR: N%d:QLM%d: Lane %d: Invalid TX_PRE(%d). TX_PRE must be <= 10.\n", |
| node, qlm, lane, tx_swing); |
| return; |
| } |
| |
| if (tx_post < -1 || tx_post > 31) { |
| printf("ERROR: N%d:QLM%d: Lane %d: Invalid TX_POST(%d). TX_POST must be <= 15.\n", |
| node, qlm, lane, tx_swing); |
| return; |
| } |
| |
| if (tx_pre >= 0 && tx_post >= 0 && tx_swing >= 0 && |
| tx_pre + tx_post - tx_swing > 2) { |
| printf("ERROR: N%d.QLM%d: Lane %d: TX_PRE(%d) + TX_POST(%d) - TX_SWING(%d) must be <= 2\n", |
| node, qlm, lane, tx_pre, tx_post, tx_swing); |
| return; |
| } |
| |
| if (tx_pre >= 0 && tx_post >= 0 && tx_swing >= 0 && |
| tx_pre + tx_post + tx_swing > 35) { |
| printf("ERROR: N%d.QLM%d: Lane %d: TX_PRE(%d) + TX_POST(%d) + TX_SWING(%d) must be <= 35\n", |
| node, qlm, lane, tx_pre, tx_post, tx_swing); |
| return; |
| } |
| |
| if (tx_gain < -1 || tx_gain > 7) { |
| printf("ERROR: N%d.QLM%d: Lane %d: Invalid TX_GAIN(%d). TX_GAIN must be between 0 and 7\n", |
| node, qlm, lane, tx_gain); |
| return; |
| } |
| |
| if (tx_vboost < -1 || tx_vboost > 1) { |
| printf("ERROR: N%d.QLM%d: Lane %d: Invalid TX_VBOOST(%d). TX_VBOOST must be 0 or 1.\n", |
| node, qlm, lane, tx_vboost); |
| return; |
| } |
| |
| debug("N%d.QLM%d: Lane %d: TX_SWING=%d, TX_PRE=%d, TX_POST=%d, TX_GAIN=%d, TX_VBOOST=%d\n", |
| node, qlm, lane, tx_swing, tx_pre, tx_post, tx_gain, tx_vboost); |
| |
| /* Complete the Tx swing and Tx equilization programming */ |
| /* 1) Enable Tx swing and Tx emphasis overrides */ |
| tx_cfg1.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_1(lane, qlm)); |
| tx_cfg1.s.tx_swing_ovrrd_en = (tx_swing != -1); |
| tx_cfg1.s.tx_premptap_ovrrd_val = (tx_pre != -1) && (tx_post != -1); |
| tx_cfg1.s.tx_vboost_en_ovrrd_en = (tx_vboost != -1); /* Vboost override */ |
| ; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_1(lane, qlm), tx_cfg1.u64); |
| /* 2) Program the Tx swing and Tx emphasis Pre-cursor and Post-cursor values */ |
| /* CFG_TX_PREMPTAP[8:4] = Lane X's TX post-cursor value (C+1) */ |
| /* CFG_TX_PREMPTAP[3:0] = Lane X's TX pre-cursor value (C-1) */ |
| if (tx_swing != -1) { |
| tx_cfg0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_0(lane, qlm)); |
| tx_cfg0.s.cfg_tx_swing = tx_swing; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_0(lane, qlm), tx_cfg0.u64); |
| } |
| |
| if ((tx_pre != -1) && (tx_post != -1)) { |
| pre_emphasis.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_PRE_EMPHASIS(lane, qlm)); |
| pre_emphasis.s.cfg_tx_premptap = (tx_post << 4) | tx_pre; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_PRE_EMPHASIS(lane, qlm), pre_emphasis.u64); |
| } |
| |
| /* Apply TX gain settings */ |
| if (tx_gain != -1) { |
| tx_cfg3.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_3(lane, qlm)); |
| tx_cfg3.s.pcs_sds_tx_gain = tx_gain; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_3(lane, qlm), tx_cfg3.u64); |
| } |
| |
| /* Apply TX vboot settings */ |
| if (tx_vboost != -1) { |
| tx_cfg3.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_3(lane, qlm)); |
| tx_cfg3.s.cfg_tx_vboost_en = tx_vboost; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_3(lane, qlm), tx_cfg3.u64); |
| } |
| |
| /* 3) Program override for the Tx coefficient request */ |
| pcs_ctlifc_0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(lane, qlm)); |
| if (((tx_pre != -1) && (tx_post != -1)) || (tx_swing != -1)) |
| pcs_ctlifc_0.s.cfg_tx_coeff_req_ovrrd_val = 0x1; |
| if (tx_vboost != -1) |
| pcs_ctlifc_0.s.cfg_tx_vboost_en_ovrrd_val = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(lane, qlm), pcs_ctlifc_0.u64); |
| |
| /* 4) Enable the Tx coefficient request override enable */ |
| pcs_ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| if (((tx_pre != -1) && (tx_post != -1)) || (tx_swing != -1)) |
| pcs_ctlifc_2.s.cfg_tx_coeff_req_ovrrd_en = 0x1; |
| if (tx_vboost != -1) |
| pcs_ctlifc_2.s.cfg_tx_vboost_en_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), pcs_ctlifc_2.u64); |
| |
| /* 5) Issue a Control Interface Configuration Override request to start the Tx equalizer */ |
| pcs_ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| pcs_ctlifc_2.s.ctlifc_ovrrd_req = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), pcs_ctlifc_2.u64); |
| |
| /* 6) Wait 1 ms for the request to complete */ |
| udelay(1000); |
| |
| /* Steps 7 & 8 required for subsequent Tx swing and Tx equilization adjustment */ |
| /* 7) Disable the Tx coefficient request override enable */ |
| pcs_ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| pcs_ctlifc_2.s.cfg_tx_coeff_req_ovrrd_en = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), pcs_ctlifc_2.u64); |
| /* 8) Issue a Control Interface Configuration Override request */ |
| pcs_ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| pcs_ctlifc_2.s.ctlifc_ovrrd_req = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), pcs_ctlifc_2.u64); |
| } |
| |
| /** |
| * Some QLM speeds need to override the default tuning parameters |
| * |
| * @param node Node to configure |
| * @param qlm QLM to configure |
| * @param baud_mhz Desired speed in MHz |
| * @param tx_swing Voltage swing. The higher the value the lower the voltage, |
| * the default value is 7. |
| * @param tx_premptap bits [0:3] pre-cursor pre-emphasis, bits[4:8] post-cursor |
| * pre-emphasis. |
| * @param tx_gain Transmit gain. Range 0-7 |
| * @param tx_vboost Transmit voltage boost. Range 0-1 |
| * |
| */ |
| void octeon_qlm_tune_v3(int node, int qlm, int baud_mhz, int tx_swing, int tx_premptap, int tx_gain, |
| int tx_vboost) |
| { |
| int lane; |
| int num_lanes = cvmx_qlm_get_lanes(qlm); |
| |
| for (lane = 0; lane < num_lanes; lane++) { |
| int tx_pre = (tx_premptap == -1) ? -1 : tx_premptap & 0xf; |
| int tx_post = (tx_premptap == -1) ? -1 : (tx_premptap >> 4) & 0x1f; |
| |
| octeon_qlm_tune_per_lane_v3(node, qlm, baud_mhz, lane, tx_swing, tx_pre, tx_post, |
| tx_gain, tx_vboost); |
| } |
| } |
| |
| /** |
| * Some QLMs need to override the default pre-ctle for low loss channels. |
| * |
| * @param node Node to configure |
| * @param qlm QLM to configure |
| * @param pre_ctle pre-ctle settings for low loss channels |
| */ |
| void octeon_qlm_set_channel_v3(int node, int qlm, int pre_ctle) |
| { |
| cvmx_gserx_lane_vma_fine_ctrl_2_t lane_vma_fine_ctrl_2; |
| |
| lane_vma_fine_ctrl_2.u64 = csr_rd_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm)); |
| lane_vma_fine_ctrl_2.s.rx_prectle_gain_min_fine = pre_ctle; |
| csr_wr_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm), lane_vma_fine_ctrl_2.u64); |
| } |
| |
| static void __qlm_init_errata_20844(int node, int qlm) |
| { |
| int lane; |
| |
| /* Only applies to CN78XX pass 1.x */ |
| if (!OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) |
| return; |
| |
| /* Errata GSER-20844: Electrical Idle logic can coast |
| * 1) After the link first comes up write the following |
| * register on each lane to prevent the application logic |
| * from stomping on the Coast inputs. This is a one time write, |
| * or if you prefer you could put it in the link up loop and |
| * write it every time the link comes up. |
| * 1a) Then write GSER(0..13)_LANE(0..3)_PCS_CTLIFC_2 |
| * Set CTLIFC_OVRRD_REQ (later) |
| * Set CFG_RX_CDR_COAST_REQ_OVRRD_EN |
| * Its not clear if #1 and #1a can be combined, lets try it |
| * this way first. |
| */ |
| for (lane = 0; lane < 4; lane++) { |
| cvmx_gserx_lanex_rx_misc_ovrrd_t misc_ovrrd; |
| cvmx_gserx_lanex_pcs_ctlifc_2_t ctlifc_2; |
| |
| ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| ctlifc_2.s.cfg_rx_cdr_coast_req_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), ctlifc_2.u64); |
| |
| misc_ovrrd.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, qlm)); |
| misc_ovrrd.s.cfg_rx_eie_det_ovrrd_en = 1; |
| misc_ovrrd.s.cfg_rx_eie_det_ovrrd_val = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, qlm), misc_ovrrd.u64); |
| |
| udelay(1); |
| |
| misc_ovrrd.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, qlm)); |
| misc_ovrrd.s.cfg_rx_eie_det_ovrrd_en = 1; |
| misc_ovrrd.s.cfg_rx_eie_det_ovrrd_val = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, qlm), misc_ovrrd.u64); |
| ctlifc_2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm)); |
| ctlifc_2.s.ctlifc_ovrrd_req = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(lane, qlm), ctlifc_2.u64); |
| } |
| } |
| |
| /** CN78xx reference clock register settings */ |
| struct refclk_settings_cn78xx { |
| bool valid; /** Reference clock speed supported */ |
| union cvmx_gserx_pll_px_mode_0 mode_0; |
| union cvmx_gserx_pll_px_mode_1 mode_1; |
| union cvmx_gserx_lane_px_mode_0 pmode_0; |
| union cvmx_gserx_lane_px_mode_1 pmode_1; |
| }; |
| |
| /** Default reference clock for various modes */ |
| static const u8 def_ref_clk_cn78xx[R_NUM_LANE_MODES] = { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }; |
| |
| /** |
| * This data structure stores the reference clock for each mode for each QLM. |
| * |
| * It is indexed first by the node number, then the QLM number and then the |
| * lane mode. It is initialized to the default values. |
| */ |
| static u8 ref_clk_cn78xx[CVMX_MAX_NODES][8][R_NUM_LANE_MODES] = { |
| { { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 } }, |
| { { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 } }, |
| { { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 } }, |
| { { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 }, |
| { 0, 0, 0, 2, 2, 2, 2, 2, 2, 1, 1, 1 } } |
| }; |
| |
| /** |
| * This data structure contains the register values for the cn78xx PLLs |
| * It is indexed first by the reference clock and second by the mode. |
| * Note that not all combinations are supported. |
| */ |
| static const struct refclk_settings_cn78xx refclk_settings_cn78xx[R_NUM_LANE_MODES][4] = { |
| { /* 0 R_2_5G_REFCLK100 */ |
| { /* 100MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x4, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 125MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 156.25MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } }, |
| { |
| /* 1 R_5G_REFCLK100 */ |
| { /* 100MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x4, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 125MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 156.25MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| }, |
| }, |
| { /* 2 R_8G_REFCLK100 */ |
| { /* 100MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x1, |
| .pll_opr = 0x1, |
| .pll_div = 0x28 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xb, |
| .ph_acc_adj = 0x23 } }, |
| { /* 125MHz reference clock */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x2, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x1, |
| .pll_opr = 0x1, |
| .pll_div = 0x20 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xb, |
| .ph_acc_adj = 0x23 } }, |
| { /* 156.25MHz reference clock not supported */ |
| .valid = false } }, |
| { |
| /* 3 R_125G_REFCLK15625_KX */ |
| { /* 100MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 156.25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x3, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| }, |
| }, |
| { /* 4 R_3125G_REFCLK15625_XAUI */ |
| { /* 100MHz reference */ |
| .valid = false }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x14 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 156.25MHz reference, default */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x14 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } }, |
| { /* 5 R_103125G_REFCLK15625_KR */ |
| { /* 100MHz reference */ |
| .valid = false }, |
| { /* 125MHz reference */ |
| .valid = false }, |
| { /* 156.25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x1, |
| .pll_div = 0x21 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x1, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0xf } }, |
| { /* 161.1328125 reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x1, |
| .pll_div = 0x20 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x1, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0xf } } }, |
| { /* 6 R_125G_REFCLK15625_SGMII */ |
| { /* 100MHz reference clock */ |
| .valid = 1, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 125MHz reference clock */ |
| .valid = 1, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 156.25MHz reference clock */ |
| .valid = 1, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0x28 }, |
| .mode_1.s = { .pll_16p5en = 0x1, |
| .pll_cpadj = 0x3, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x2, |
| .rx_ldiv = 0x2, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } } }, |
| { /* 7 R_5G_REFCLK15625_QSGMII */ |
| { /* 100MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x4, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, .pll_cpadj = 0x2, .pll_pcie3en = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, .pll_cpadj = 0x1, .pll_pcie3en = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { /* 156.25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, .pll_cpadj = 0x2, .pll_pcie3en = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xc, |
| .ph_acc_adj = 0x1e } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } }, |
| { /* 8 R_625G_REFCLK15625_RXAUI */ |
| { /* 100MHz reference */ |
| .valid = false }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 156.25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 161.1328125 reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x1, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } } }, |
| { /* 9 R_2_5G_REFCLK125 */ |
| { /* 100MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x4, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 156,25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0x5 }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x1, |
| .rx_ldiv = 0x1, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x1, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } }, |
| { /* 0xa R_5G_REFCLK125 */ |
| { /* 100MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x4, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x19 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x14 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { /* 156.25MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x3, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x0, |
| .pll_opr = 0x0, |
| .pll_div = 0x10 }, |
| .pmode_0.s = { .ctle = 0x0, |
| .pcie = 0x1, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xa, |
| .ph_acc_adj = 0x14 } }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } }, |
| { /* 0xb R_8G_REFCLK125 */ |
| { /* 100MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x3, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x2, |
| .pll_pcie3en = 0x1, |
| .pll_opr = 0x1, |
| .pll_div = 0x28 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xb, |
| .ph_acc_adj = 0x23 } }, |
| { /* 125MHz reference */ |
| .valid = true, |
| .mode_0.s = { .pll_icp = 0x2, .pll_rloop = 0x5, .pll_pcs_div = 0xa }, |
| .mode_1.s = { .pll_16p5en = 0x0, |
| .pll_cpadj = 0x1, |
| .pll_pcie3en = 0x1, |
| .pll_opr = 0x1, |
| .pll_div = 0x20 }, |
| .pmode_0.s = { .ctle = 0x3, |
| .pcie = 0x0, |
| .tx_ldiv = 0x0, |
| .rx_ldiv = 0x0, |
| .srate = 0x0, |
| .tx_mode = 0x3, |
| .rx_mode = 0x3 }, |
| .pmode_1.s = { .vma_fine_cfg_sel = 0x0, |
| .vma_mm = 0x0, |
| .cdr_fgain = 0xb, |
| .ph_acc_adj = 0x23 } }, |
| { /* 156.25MHz reference */ |
| .valid = false }, |
| { |
| /* 161.1328125MHz reference clock */ |
| .valid = false, |
| } } |
| }; |
| |
| /** |
| * Set a non-standard reference clock for a node, qlm and lane mode. |
| * |
| * @INTERNAL |
| * |
| * @param node node number the reference clock is used with |
| * @param qlm qlm number the reference clock is hooked up to |
| * @param lane_mode current lane mode selected for the QLM |
| * @param ref_clk_sel 0 = 100MHz, 1 = 125MHz, 2 = 156.25MHz, |
| * 3 = 161.1328125MHz |
| * |
| * @return 0 for success or -1 if the reference clock selector is not supported |
| * |
| * NOTE: This must be called before __qlm_setup_pll_cn78xx. |
| */ |
| static int __set_qlm_ref_clk_cn78xx(int node, int qlm, int lane_mode, int ref_clk_sel) |
| { |
| if (ref_clk_sel > 3 || ref_clk_sel < 0 || |
| !refclk_settings_cn78xx[lane_mode][ref_clk_sel].valid) { |
| debug("%s: Invalid reference clock %d for lane mode %d for node %d, QLM %d\n", |
| __func__, ref_clk_sel, lane_mode, node, qlm); |
| return -1; |
| } |
| debug("%s(%d, %d, 0x%x, %d)\n", __func__, node, qlm, lane_mode, ref_clk_sel); |
| ref_clk_cn78xx[node][qlm][lane_mode] = ref_clk_sel; |
| return 0; |
| } |
| |
| /** |
| * KR - Inverted Tx Coefficient Direction Change. Changing Pre & Post Tap inc/dec direction |
| * |
| * |
| * @INTERNAL |
| * |
| * @param node Node number to configure |
| * @param qlm QLM number to configure |
| */ |
| static void __qlm_kr_inc_dec_gser26636(int node, int qlm) |
| { |
| cvmx_gserx_rx_txdir_ctrl_1_t rx_txdir_ctrl; |
| |
| /* Apply workaround for Errata GSER-26636, |
| * KR training coefficient update inverted |
| */ |
| rx_txdir_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_RX_TXDIR_CTRL_1(qlm)); |
| rx_txdir_ctrl.s.rx_precorr_chg_dir = 1; |
| rx_txdir_ctrl.s.rx_tap1_chg_dir = 1; |
| csr_wr_node(node, CVMX_GSERX_RX_TXDIR_CTRL_1(qlm), rx_txdir_ctrl.u64); |
| } |
| |
| /** |
| * Updating the RX EQ settings to support wider temperature range |
| * @INTERNAL |
| * |
| * @param node Node number to configure |
| * @param qlm QLM number to configure |
| */ |
| static void __qlm_rx_eq_temp_gser27140(int node, int qlm) |
| { |
| int lane; |
| int num_lanes = cvmx_qlm_get_lanes(qlm); |
| cvmx_gserx_lanex_rx_valbbd_ctrl_0_t rx_valbbd_ctrl_0; |
| cvmx_gserx_lane_vma_fine_ctrl_2_t lane_vma_fine_ctrl_2; |
| cvmx_gserx_lane_vma_fine_ctrl_0_t lane_vma_fine_ctrl_0; |
| cvmx_gserx_rx_txdir_ctrl_1_t rx_txdir_ctrl_1; |
| cvmx_gserx_eq_wait_time_t eq_wait_time; |
| cvmx_gserx_rx_txdir_ctrl_2_t rx_txdir_ctrl_2; |
| cvmx_gserx_rx_txdir_ctrl_0_t rx_txdir_ctrl_0; |
| |
| for (lane = 0; lane < num_lanes; lane++) { |
| rx_valbbd_ctrl_0.u64 = |
| csr_rd_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(lane, qlm)); |
| rx_valbbd_ctrl_0.s.agc_gain = 3; |
| rx_valbbd_ctrl_0.s.dfe_gain = 2; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_VALBBD_CTRL_0(lane, qlm), |
| rx_valbbd_ctrl_0.u64); |
| } |
| |
| /* do_pre_ctle_limits_work_around: */ |
| lane_vma_fine_ctrl_2.u64 = csr_rd_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm)); |
| //lane_vma_fine_ctrl_2.s.rx_prectle_peak_max_fine = 11; |
| lane_vma_fine_ctrl_2.s.rx_prectle_gain_max_fine = 11; |
| //lane_vma_fine_ctrl_2.s.rx_prectle_peak_min_fine = 6; |
| lane_vma_fine_ctrl_2.s.rx_prectle_gain_min_fine = 6; |
| csr_wr_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_2(qlm), lane_vma_fine_ctrl_2.u64); |
| |
| /* do_inc_dec_thres_work_around: */ |
| rx_txdir_ctrl_0.u64 = csr_rd_node(node, CVMX_GSERX_RX_TXDIR_CTRL_0(qlm)); |
| rx_txdir_ctrl_0.s.rx_boost_hi_thrs = 11; |
| rx_txdir_ctrl_0.s.rx_boost_lo_thrs = 4; |
| rx_txdir_ctrl_0.s.rx_boost_hi_val = 15; |
| csr_wr_node(node, CVMX_GSERX_RX_TXDIR_CTRL_0(qlm), rx_txdir_ctrl_0.u64); |
| |
| /* do_sdll_iq_work_around: */ |
| lane_vma_fine_ctrl_0.u64 = csr_rd_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_0(qlm)); |
| lane_vma_fine_ctrl_0.s.rx_sdll_iq_max_fine = 14; |
| lane_vma_fine_ctrl_0.s.rx_sdll_iq_min_fine = 8; |
| lane_vma_fine_ctrl_0.s.rx_sdll_iq_step_fine = 2; |
| |
| /* do_vma_window_work_around_2: */ |
| lane_vma_fine_ctrl_0.s.vma_window_wait_fine = 5; |
| lane_vma_fine_ctrl_0.s.lms_wait_time_fine = 5; |
| |
| csr_wr_node(node, CVMX_GSERX_LANE_VMA_FINE_CTRL_0(qlm), lane_vma_fine_ctrl_0.u64); |
| |
| /* Set dfe_tap_1_lo_thres_val: */ |
| rx_txdir_ctrl_1.u64 = csr_rd_node(node, CVMX_GSERX_RX_TXDIR_CTRL_1(qlm)); |
| rx_txdir_ctrl_1.s.rx_tap1_lo_thrs = 8; |
| rx_txdir_ctrl_1.s.rx_tap1_hi_thrs = 0x17; |
| csr_wr_node(node, CVMX_GSERX_RX_TXDIR_CTRL_1(qlm), rx_txdir_ctrl_1.u64); |
| |
| /* do_rxeq_wait_cnt_work_around: */ |
| eq_wait_time.u64 = csr_rd_node(node, CVMX_GSERX_EQ_WAIT_TIME(qlm)); |
| eq_wait_time.s.rxeq_wait_cnt = 6; |
| csr_wr_node(node, CVMX_GSERX_EQ_WAIT_TIME(qlm), eq_wait_time.u64); |
| |
| /* do_write_rx_txdir_precorr_thresholds: */ |
| rx_txdir_ctrl_2.u64 = csr_rd_node(node, CVMX_GSERX_RX_TXDIR_CTRL_2(qlm)); |
| rx_txdir_ctrl_2.s.rx_precorr_hi_thrs = 0xc0; |
| rx_txdir_ctrl_2.s.rx_precorr_lo_thrs = 0x40; |
| csr_wr_node(node, CVMX_GSERX_RX_TXDIR_CTRL_2(qlm), rx_txdir_ctrl_2.u64); |
| } |
| |
| /* Errata GSER-26150: 10G PHY PLL Temperature Failure |
| * This workaround must be completed after the final deassertion of |
| * GSERx_PHY_CTL[PHY_RESET] |
| */ |
| static int __qlm_errata_gser_26150(int node, int qlm, int is_pcie) |
| { |
| int num_lanes = 4; |
| int i; |
| cvmx_gserx_glbl_pll_cfg_3_t pll_cfg_3; |
| cvmx_gserx_glbl_misc_config_1_t misc_config_1; |
| |
| /* PCIe only requires the LC-VCO parameters to be updated */ |
| if (is_pcie) { |
| /* Update PLL parameters */ |
| /* Step 1: Set GSER()_GLBL_PLL_CFG_3[PLL_VCTRL_SEL_LCVCO_VAL] = 0x2, and |
| * GSER()_GLBL_PLL_CFG_3[PCS_SDS_PLL_VCO_AMP] = 0 |
| */ |
| pll_cfg_3.u64 = csr_rd_node(node, CVMX_GSERX_GLBL_PLL_CFG_3(qlm)); |
| pll_cfg_3.s.pcs_sds_pll_vco_amp = 0; |
| pll_cfg_3.s.pll_vctrl_sel_lcvco_val = 2; |
| csr_wr_node(node, CVMX_GSERX_GLBL_PLL_CFG_3(qlm), pll_cfg_3.u64); |
| |
| /* Step 2: Set GSER()_GLBL_MISC_CONFIG_1[PCS_SDS_TRIM_CHP_REG] = 0x2. */ |
| misc_config_1.u64 = csr_rd_node(node, CVMX_GSERX_GLBL_MISC_CONFIG_1(qlm)); |
| misc_config_1.s.pcs_sds_trim_chp_reg = 2; |
| csr_wr_node(node, CVMX_GSERX_GLBL_MISC_CONFIG_1(qlm), misc_config_1.u64); |
| return 0; |
| } |
| |
| /* Applying this errata twice causes problems */ |
| pll_cfg_3.u64 = csr_rd_node(node, CVMX_GSERX_GLBL_PLL_CFG_3(qlm)); |
| if (pll_cfg_3.s.pll_vctrl_sel_lcvco_val == 0x2) |
| return 0; |
| |
| /* (GSER-26150) 10 Gb temperature excursions can cause lock failure */ |
| /* Change the calibration point of the VCO at start up to shift some |
| * available range of the VCO from -deltaT direction to the +deltaT |
| * ramp direction allowing a greater range of VCO temperatures before |
| * experiencing the failure. |
| */ |
| |
| /* Check for DLMs on CN73XX and CNF75XX */ |
| if (OCTEON_IS_MODEL(OCTEON_CN73XX) && (qlm == 5 || qlm == 6)) |
| num_lanes = 2; |
| |
| /* Put PHY in P2 Power-down state Need to Power down all lanes in a |
| * QLM/DLM to force PHY to P2 state |
| */ |
| for (i = 0; i < num_lanes; i++) { |
| cvmx_gserx_lanex_pcs_ctlifc_0_t ctlifc0; |
| cvmx_gserx_lanex_pcs_ctlifc_1_t ctlifc1; |
| cvmx_gserx_lanex_pcs_ctlifc_2_t ctlifc2; |
| |
| /* Step 1: Set Set GSER()_LANE(lane_n)_PCS_CTLIFC_0[CFG_TX_PSTATE_REQ_OVERRD_VAL] |
| * = 0x3 |
| * Select P2 power state for Tx lane |
| */ |
| ctlifc0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(i, qlm)); |
| ctlifc0.s.cfg_tx_pstate_req_ovrrd_val = 0x3; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(i, qlm), ctlifc0.u64); |
| /* Step 2: Set GSER()_LANE(lane_n)_PCS_CTLIFC_1[CFG_RX_PSTATE_REQ_OVERRD_VAL] |
| * = 0x3 |
| * Select P2 power state for Rx lane |
| */ |
| ctlifc1.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_1(i, qlm)); |
| ctlifc1.s.cfg_rx_pstate_req_ovrrd_val = 0x3; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_1(i, qlm), ctlifc1.u64); |
| /* Step 3: Set GSER()_LANE(lane_n)_PCS_CTLIFC_2[CFG_TX_PSTATE_REQ_OVRRD_EN] = 1 |
| * Enable Tx power state override and Set |
| * GSER()_LANE(lane_n)_PCS_CTLIFC_2[CFG_RX_PSTATE_REQ_OVRRD_EN] = 1 |
| * Enable Rx power state override |
| */ |
| ctlifc2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm)); |
| ctlifc2.s.cfg_tx_pstate_req_ovrrd_en = 0x1; |
| ctlifc2.s.cfg_rx_pstate_req_ovrrd_en = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm), ctlifc2.u64); |
| /* Step 4: Set GSER()_LANE(lane_n)_PCS_CTLIFC_2[CTLIFC_OVRRD_REQ] = 1 |
| * Start the CTLIFC override state machine |
| */ |
| ctlifc2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm)); |
| ctlifc2.s.ctlifc_ovrrd_req = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm), ctlifc2.u64); |
| } |
| |
| /* Update PLL parameters */ |
| /* Step 5: Set GSER()_GLBL_PLL_CFG_3[PLL_VCTRL_SEL_LCVCO_VAL] = 0x2, and |
| * GSER()_GLBL_PLL_CFG_3[PCS_SDS_PLL_VCO_AMP] = 0 |
| */ |
| pll_cfg_3.u64 = csr_rd_node(node, CVMX_GSERX_GLBL_PLL_CFG_3(qlm)); |
| pll_cfg_3.s.pcs_sds_pll_vco_amp = 0; |
| pll_cfg_3.s.pll_vctrl_sel_lcvco_val = 2; |
| csr_wr_node(node, CVMX_GSERX_GLBL_PLL_CFG_3(qlm), pll_cfg_3.u64); |
| |
| /* Step 6: Set GSER()_GLBL_MISC_CONFIG_1[PCS_SDS_TRIM_CHP_REG] = 0x2. */ |
| misc_config_1.u64 = csr_rd_node(node, CVMX_GSERX_GLBL_MISC_CONFIG_1(qlm)); |
| misc_config_1.s.pcs_sds_trim_chp_reg = 2; |
| csr_wr_node(node, CVMX_GSERX_GLBL_MISC_CONFIG_1(qlm), misc_config_1.u64); |
| |
| /* Wake up PHY and transition to P0 Power-up state to bring-up the lanes, |
| * need to wake up all PHY lanes |
| */ |
| for (i = 0; i < num_lanes; i++) { |
| cvmx_gserx_lanex_pcs_ctlifc_0_t ctlifc0; |
| cvmx_gserx_lanex_pcs_ctlifc_1_t ctlifc1; |
| cvmx_gserx_lanex_pcs_ctlifc_2_t ctlifc2; |
| /* Step 7: Set GSER()_LANE(lane_n)_PCS_CTLIFC_0[CFG_TX_PSTATE_REQ_OVERRD_VAL] = 0x0 |
| * Select P0 power state for Tx lane |
| */ |
| ctlifc0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(i, qlm)); |
| ctlifc0.s.cfg_tx_pstate_req_ovrrd_val = 0x0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_0(i, qlm), ctlifc0.u64); |
| /* Step 8: Set GSER()_LANE(lane_n)_PCS_CTLIFC_1[CFG_RX_PSTATE_REQ_OVERRD_VAL] = 0x0 |
| * Select P0 power state for Rx lane |
| */ |
| ctlifc1.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_1(i, qlm)); |
| ctlifc1.s.cfg_rx_pstate_req_ovrrd_val = 0x0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_1(i, qlm), ctlifc1.u64); |
| /* Step 9: Set GSER()_LANE(lane_n)_PCS_CTLIFC_2[CFG_TX_PSTATE_REQ_OVRRD_EN] = 1 |
| * Enable Tx power state override and Set |
| * GSER()_LANE(lane_n)_PCS_CTLIFC_2[CFG_RX_PSTATE_REQ_OVRRD_EN] = 1 |
| * Enable Rx power state override |
| */ |
| ctlifc2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm)); |
| ctlifc2.s.cfg_tx_pstate_req_ovrrd_en = 0x1; |
| ctlifc2.s.cfg_rx_pstate_req_ovrrd_en = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm), ctlifc2.u64); |
| /* Step 10: Set GSER()_LANE(lane_n)_PCS_CTLIFC_2[CTLIFC_OVRRD_REQ] = 1 |
| * Start the CTLIFC override state machine |
| */ |
| ctlifc2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm)); |
| ctlifc2.s.ctlifc_ovrrd_req = 0x1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm), ctlifc2.u64); |
| } |
| |
| /* Step 11: Wait 10 msec */ |
| mdelay(10); |
| |
| /* Release Lane Tx/Rx Power state override enables. */ |
| for (i = 0; i < num_lanes; i++) { |
| cvmx_gserx_lanex_pcs_ctlifc_2_t ctlifc2; |
| |
| ctlifc2.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm)); |
| ctlifc2.s.cfg_tx_pstate_req_ovrrd_en = 0x0; |
| ctlifc2.s.cfg_rx_pstate_req_ovrrd_en = 0x0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PCS_CTLIFC_2(i, qlm), ctlifc2.u64); |
| } |
| |
| /* Step 12: Poll GSER()_PLL_STAT.[PLL_LOCK] = 1 |
| * Poll and check that PLL is locked |
| */ |
| if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_GSERX_PLL_STAT(qlm), cvmx_gserx_pll_stat_t, |
| pll_lock, ==, 1, 10000)) { |
| printf("%d:QLM%d: Timeout waiting for GSERX_PLL_STAT[pll_lock]\n", node, qlm); |
| return -1; |
| } |
| |
| /* Step 13: Poll GSER()_QLM_STAT.[RST_RDY] = 1 |
| * Poll and check that QLM/DLM is Ready |
| */ |
| if (is_pcie == 0 && |
| CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_GSERX_QLM_STAT(qlm), cvmx_gserx_qlm_stat_t, |
| rst_rdy, ==, 1, 10000)) { |
| printf("%d:QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", node, qlm); |
| return -1; |
| } |
| |
| return 0; |
| } |
| |
| /** |
| * Configure all of the PLLs for a particular node and qlm |
| * @INTERNAL |
| * |
| * @param node Node number to configure |
| * @param qlm QLM number to configure |
| */ |
| static void __qlm_setup_pll_cn78xx(int node, int qlm) |
| { |
| cvmx_gserx_pll_px_mode_0_t mode_0; |
| cvmx_gserx_pll_px_mode_1_t mode_1; |
| cvmx_gserx_lane_px_mode_0_t pmode_0; |
| cvmx_gserx_lane_px_mode_1_t pmode_1; |
| int lane_mode; |
| int ref_clk; |
| const struct refclk_settings_cn78xx *clk_settings; |
| |
| for (lane_mode = 0; lane_mode < R_NUM_LANE_MODES; lane_mode++) { |
| mode_0.u64 = csr_rd_node(node, CVMX_GSERX_PLL_PX_MODE_0(lane_mode, qlm)); |
| mode_1.u64 = csr_rd_node(node, CVMX_GSERX_PLL_PX_MODE_1(lane_mode, qlm)); |
| pmode_0.u64 = 0; |
| pmode_1.u64 = 0; |
| ref_clk = ref_clk_cn78xx[node][qlm][lane_mode]; |
| clk_settings = &refclk_settings_cn78xx[lane_mode][ref_clk]; |
| debug("%s(%d, %d): lane_mode: 0x%x, ref_clk: %d\n", __func__, node, qlm, lane_mode, |
| ref_clk); |
| |
| if (!clk_settings->valid) { |
| printf("%s: Error: reference clock %d is not supported for lane mode %d on qlm %d\n", |
| __func__, ref_clk, lane_mode, qlm); |
| continue; |
| } |
| |
| mode_0.s.pll_icp = clk_settings->mode_0.s.pll_icp; |
| mode_0.s.pll_rloop = clk_settings->mode_0.s.pll_rloop; |
| mode_0.s.pll_pcs_div = clk_settings->mode_0.s.pll_pcs_div; |
| |
| mode_1.s.pll_16p5en = clk_settings->mode_1.s.pll_16p5en; |
| mode_1.s.pll_cpadj = clk_settings->mode_1.s.pll_cpadj; |
| mode_1.s.pll_pcie3en = clk_settings->mode_1.s.pll_pcie3en; |
| mode_1.s.pll_opr = clk_settings->mode_1.s.pll_opr; |
| mode_1.s.pll_div = clk_settings->mode_1.s.pll_div; |
| |
| pmode_0.u64 = clk_settings->pmode_0.u64; |
| |
| pmode_1.u64 = clk_settings->pmode_1.u64; |
| |
| csr_wr_node(node, CVMX_GSERX_PLL_PX_MODE_1(lane_mode, qlm), mode_1.u64); |
| csr_wr_node(node, CVMX_GSERX_LANE_PX_MODE_0(lane_mode, qlm), pmode_0.u64); |
| csr_wr_node(node, CVMX_GSERX_LANE_PX_MODE_1(lane_mode, qlm), pmode_1.u64); |
| csr_wr_node(node, CVMX_GSERX_PLL_PX_MODE_0(lane_mode, qlm), mode_0.u64); |
| } |
| } |
| |
| /** |
| * Get the lane mode for the specified node and QLM. |
| * |
| * @param ref_clk_sel The reference-clock selection to use to configure QLM |
| * 0 = REF_100MHZ |
| * 1 = REF_125MHZ |
| * 2 = REF_156MHZ |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param[out] alt_pll_settings If non-NULL this will be set if non-default PLL |
| * settings are required for the mode. |
| * |
| * @return lane mode to use or -1 on error |
| * |
| * NOTE: In some modes |
| */ |
| static int __get_lane_mode_for_speed_and_ref_clk(int ref_clk_sel, int baud_mhz, |
| bool *alt_pll_settings) |
| { |
| if (alt_pll_settings) |
| *alt_pll_settings = false; |
| switch (baud_mhz) { |
| case 98304: |
| case 49152: |
| case 24576: |
| case 12288: |
| if (ref_clk_sel != 3) { |
| printf("Error: Invalid ref clock\n"); |
| return -1; |
| } |
| return 0x5; |
| case 6144: |
| case 3072: |
| if (ref_clk_sel != 3) { |
| printf("Error: Invalid ref clock\n"); |
| return -1; |
| } |
| return 0x8; |
| case 1250: |
| if (alt_pll_settings) |
| *alt_pll_settings = (ref_clk_sel != 2); |
| return R_125G_REFCLK15625_SGMII; |
| case 2500: |
| if (ref_clk_sel == 0) |
| return R_2_5G_REFCLK100; |
| |
| if (alt_pll_settings) |
| *alt_pll_settings = (ref_clk_sel != 1); |
| return R_2_5G_REFCLK125; |
| case 3125: |
| if (ref_clk_sel == 2) { |
| return R_3125G_REFCLK15625_XAUI; |
| } else if (ref_clk_sel == 1) { |
| if (alt_pll_settings) |
| *alt_pll_settings = true; |
| return R_3125G_REFCLK15625_XAUI; |
| } |
| |
| printf("Error: Invalid speed\n"); |
| return -1; |
| case 5000: |
| if (ref_clk_sel == 0) { |
| return R_5G_REFCLK100; |
| } else if (ref_clk_sel == 1) { |
| if (alt_pll_settings) |
| *alt_pll_settings = (ref_clk_sel != 1); |
| return R_5G_REFCLK125; |
| } else { |
| return R_5G_REFCLK15625_QSGMII; |
| } |
| case 6250: |
| if (ref_clk_sel != 0) { |
| if (alt_pll_settings) |
| *alt_pll_settings = (ref_clk_sel != 2); |
| return R_625G_REFCLK15625_RXAUI; |
| } |
| |
| printf("Error: Invalid speed\n"); |
| return -1; |
| case 6316: |
| if (ref_clk_sel != 3) { |
| printf("Error: Invalid speed\n"); |
| } else { |
| *alt_pll_settings = true; |
| return R_625G_REFCLK15625_RXAUI; |
| } |
| case 8000: |
| if (ref_clk_sel == 0) |
| return R_8G_REFCLK100; |
| else if (ref_clk_sel == 1) |
| return R_8G_REFCLK125; |
| |
| printf("Error: Invalid speed\n"); |
| return -1; |
| case 103125: |
| if (ref_clk_sel == 3 && alt_pll_settings) |
| *alt_pll_settings = true; |
| |
| if (ref_clk_sel == 2 || ref_clk_sel == 3) |
| return R_103125G_REFCLK15625_KR; |
| |
| default: |
| printf("Error: Invalid speed\n"); |
| return -1; |
| } |
| |
| return -1; |
| } |
| |
| /* |
| * Errata PEM-31375 PEM RSL accesses to PCLK registers can timeout |
| * during speed change. Change SLI_WINDOW_CTL[time] to 525us |
| */ |
| static void __set_sli_window_ctl_errata_31375(int node) |
| { |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX) || OCTEON_IS_MODEL(OCTEON_CN73XX) || |
| OCTEON_IS_MODEL(OCTEON_CNF75XX)) { |
| cvmx_sli_window_ctl_t window_ctl; |
| |
| window_ctl.u64 = csr_rd_node(node, CVMX_PEXP_SLI_WINDOW_CTL); |
| /* Configure SLI_WINDOW_CTL only once */ |
| if (window_ctl.s.time != 8191) |
| return; |
| |
| window_ctl.s.time = gd->bus_clk * 525ull / 1000000; |
| csr_wr_node(node, CVMX_PEXP_SLI_WINDOW_CTL, window_ctl.u64); |
| } |
| } |
| |
| static void __cvmx_qlm_pcie_errata_ep_cn78xx(int node, int pem) |
| { |
| cvmx_pciercx_cfg031_t cfg031; |
| cvmx_pciercx_cfg032_t cfg032; |
| cvmx_pciercx_cfg040_t cfg040; |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| int low_qlm, high_qlm; |
| int qlm, lane; |
| u64 start_cycle; |
| |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(pem)); |
| |
| /* Errata (GSER-21178) PCIe gen3 doesn't work, continued */ |
| |
| /* Wait for the link to come up as Gen1 */ |
| printf("PCIe%d: Waiting for EP out of reset\n", pem); |
| while (pemx_on.s.pemoor == 0) { |
| udelay(1000); |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(pem)); |
| } |
| |
| /* Enable gen3 speed selection */ |
| printf("PCIe%d: Enabling Gen3 for EP\n", pem); |
| /* Force Gen1 for initial link bringup. We'll fix it later */ |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(pem)); |
| pemx_cfg.s.md = 2; |
| csr_wr_node(node, CVMX_PEMX_CFG(pem), pemx_cfg.u64); |
| cfg031.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG031(pem)); |
| cfg031.s.mls = 2; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG031(pem), cfg031.u32); |
| cfg040.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG040(pem)); |
| cfg040.s.tls = 3; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG040(pem), cfg040.u32); |
| |
| /* Wait up to 10ms for the link speed change to complete */ |
| start_cycle = get_timer(0); |
| do { |
| if (get_timer(start_cycle) > 10) |
| return; |
| |
| mdelay(1); |
| cfg032.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG032(pem)); |
| } while (cfg032.s.ls != 3); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(pem)); |
| low_qlm = pem; /* FIXME */ |
| high_qlm = (pemx_cfg.cn78xx.lanes8) ? low_qlm + 1 : low_qlm; |
| |
| /* Toggle cfg_rx_dll_locken_ovrrd_en and rx_resetn_ovrrd_en across |
| * all QM lanes in use |
| */ |
| for (qlm = low_qlm; qlm <= high_qlm; qlm++) { |
| for (lane = 0; lane < 4; lane++) { |
| cvmx_gserx_lanex_rx_misc_ovrrd_t misc_ovrrd; |
| cvmx_gserx_lanex_pwr_ctrl_t pwr_ctrl; |
| |
| misc_ovrrd.u64 = |
| csr_rd_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, pem)); |
| misc_ovrrd.s.cfg_rx_dll_locken_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, pem), |
| misc_ovrrd.u64); |
| pwr_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PWR_CTRL(lane, pem)); |
| pwr_ctrl.s.rx_resetn_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PWR_CTRL(lane, pem), pwr_ctrl.u64); |
| } |
| } |
| for (qlm = low_qlm; qlm <= high_qlm; qlm++) { |
| for (lane = 0; lane < 4; lane++) { |
| cvmx_gserx_lanex_rx_misc_ovrrd_t misc_ovrrd; |
| cvmx_gserx_lanex_pwr_ctrl_t pwr_ctrl; |
| |
| misc_ovrrd.u64 = |
| csr_rd_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, pem)); |
| misc_ovrrd.s.cfg_rx_dll_locken_ovrrd_en = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_MISC_OVRRD(lane, pem), |
| misc_ovrrd.u64); |
| pwr_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PWR_CTRL(lane, pem)); |
| pwr_ctrl.s.rx_resetn_ovrrd_en = 0; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PWR_CTRL(lane, pem), pwr_ctrl.u64); |
| } |
| } |
| |
| //printf("PCIe%d: Waiting for EP link up at Gen3\n", pem); |
| if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_PEMX_ON(pem), cvmx_pemx_on_t, pemoor, ==, 1, |
| 1000000)) { |
| printf("PCIe%d: Timeout waiting for EP link up at Gen3\n", pem); |
| return; |
| } |
| } |
| |
| static void __cvmx_qlm_pcie_errata_cn78xx(int node, int qlm) |
| { |
| int pem, i, q; |
| int is_8lanes; |
| int is_high_lanes; |
| int low_qlm, high_qlm, is_host; |
| int need_ep_monitor; |
| cvmx_pemx_cfg_t pem_cfg, pem3_cfg; |
| cvmx_gserx_slice_cfg_t slice_cfg; |
| cvmx_gserx_rx_pwr_ctrl_p1_t pwr_ctrl_p1; |
| cvmx_rst_soft_prstx_t soft_prst; |
| |
| /* Only applies to CN78XX pass 1.x */ |
| if (!OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_X)) |
| return; |
| |
| /* Determine the PEM for this QLM, whether we're in 8 lane mode, |
| * and whether these are the top lanes of the 8 |
| */ |
| switch (qlm) { |
| case 0: /* First 4 lanes of PEM0 */ |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(0)); |
| pem = 0; |
| is_8lanes = pem_cfg.cn78xx.lanes8; |
| is_high_lanes = 0; |
| break; |
| case 1: /* Either last 4 lanes of PEM0, or PEM1 */ |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(0)); |
| pem = (pem_cfg.cn78xx.lanes8) ? 0 : 1; |
| is_8lanes = pem_cfg.cn78xx.lanes8; |
| is_high_lanes = is_8lanes; |
| break; |
| case 2: /* First 4 lanes of PEM2 */ |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(2)); |
| pem = 2; |
| is_8lanes = pem_cfg.cn78xx.lanes8; |
| is_high_lanes = 0; |
| break; |
| case 3: /* Either last 4 lanes of PEM2, or PEM3 */ |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(2)); |
| pem3_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(3)); |
| pem = (pem_cfg.cn78xx.lanes8) ? 2 : 3; |
| is_8lanes = (pem == 2) ? pem_cfg.cn78xx.lanes8 : pem3_cfg.cn78xx.lanes8; |
| is_high_lanes = (pem == 2) && is_8lanes; |
| break; |
| case 4: /* Last 4 lanes of PEM3 */ |
| pem = 3; |
| is_8lanes = 1; |
| is_high_lanes = 1; |
| break; |
| default: |
| return; |
| } |
| |
| /* These workaround must be applied once per PEM. Since we're called per |
| * QLM, wait for the 2nd half of 8 lane setups before doing the workaround |
| */ |
| if (is_8lanes && !is_high_lanes) |
| return; |
| |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(pem)); |
| is_host = pem_cfg.cn78xx.hostmd; |
| low_qlm = (is_8lanes) ? qlm - 1 : qlm; |
| high_qlm = qlm; |
| qlm = -1; |
| |
| if (!is_host) { |
| /* Read the current slice config value. If its at the value we will |
| * program then skip doing the workaround. We're probably doing a |
| * hot reset and the workaround is already applied |
| */ |
| slice_cfg.u64 = csr_rd_node(node, CVMX_GSERX_SLICE_CFG(low_qlm)); |
| if (slice_cfg.s.tx_rx_detect_lvl_enc == 7 && OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) |
| return; |
| } |
| |
| if (is_host && OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) { |
| /* (GSER-XXXX) GSER PHY needs to be reset at initialization */ |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| |
| for (q = low_qlm; q <= high_qlm; q++) { |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(q)); |
| phy_ctl.s.phy_reset = 1; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(q), phy_ctl.u64); |
| } |
| udelay(5); |
| |
| for (q = low_qlm; q <= high_qlm; q++) { |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(q)); |
| phy_ctl.s.phy_reset = 0; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(q), phy_ctl.u64); |
| } |
| udelay(5); |
| } |
| |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) { |
| /* (GSER-20936) GSER has wrong PCIe RX detect reset value */ |
| for (q = low_qlm; q <= high_qlm; q++) { |
| slice_cfg.u64 = csr_rd_node(node, CVMX_GSERX_SLICE_CFG(q)); |
| slice_cfg.s.tx_rx_detect_lvl_enc = 7; |
| csr_wr_node(node, CVMX_GSERX_SLICE_CFG(q), slice_cfg.u64); |
| } |
| |
| /* Clear the bit in GSERX_RX_PWR_CTRL_P1[p1_rx_subblk_pd] |
| * that coresponds to "Lane DLL" |
| */ |
| for (q = low_qlm; q <= high_qlm; q++) { |
| pwr_ctrl_p1.u64 = csr_rd_node(node, CVMX_GSERX_RX_PWR_CTRL_P1(q)); |
| pwr_ctrl_p1.s.p1_rx_subblk_pd &= ~4; |
| csr_wr_node(node, CVMX_GSERX_RX_PWR_CTRL_P1(q), pwr_ctrl_p1.u64); |
| } |
| |
| /* Errata (GSER-20888) GSER incorrect synchronizers hurts PCIe |
| * Override TX Power State machine TX reset control signal |
| */ |
| for (q = low_qlm; q <= high_qlm; q++) { |
| for (i = 0; i < 4; i++) { |
| cvmx_gserx_lanex_tx_cfg_0_t tx_cfg; |
| cvmx_gserx_lanex_pwr_ctrl_t pwr_ctrl; |
| |
| tx_cfg.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_0(i, q)); |
| tx_cfg.s.tx_resetn_ovrrd_val = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_0(i, q), tx_cfg.u64); |
| pwr_ctrl.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_PWR_CTRL(i, q)); |
| pwr_ctrl.s.tx_p2s_resetn_ovrrd_en = 1; |
| csr_wr_node(node, CVMX_GSERX_LANEX_PWR_CTRL(i, q), pwr_ctrl.u64); |
| } |
| } |
| } |
| |
| if (!is_host) { |
| cvmx_pciercx_cfg089_t cfg089; |
| cvmx_pciercx_cfg090_t cfg090; |
| cvmx_pciercx_cfg091_t cfg091; |
| cvmx_pciercx_cfg092_t cfg092; |
| cvmx_pciercx_cfg548_t cfg548; |
| cvmx_pciercx_cfg554_t cfg554; |
| |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) { |
| /* Errata (GSER-21178) PCIe gen3 doesn't work */ |
| /* The starting equalization hints are incorrect on CN78XX pass 1.x. Fix |
| * them for the 8 possible lanes. It doesn't hurt to program them even |
| * for lanes not in use |
| */ |
| cfg089.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG089(pem)); |
| cfg089.s.l1urph = 2; |
| cfg089.s.l1utp = 7; |
| cfg089.s.l0urph = 2; |
| cfg089.s.l0utp = 7; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG089(pem), cfg089.u32); |
| cfg090.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG090(pem)); |
| cfg090.s.l3urph = 2; |
| cfg090.s.l3utp = 7; |
| cfg090.s.l2urph = 2; |
| cfg090.s.l2utp = 7; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG090(pem), cfg090.u32); |
| cfg091.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG091(pem)); |
| cfg091.s.l5urph = 2; |
| cfg091.s.l5utp = 7; |
| cfg091.s.l4urph = 2; |
| cfg091.s.l4utp = 7; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG091(pem), cfg091.u32); |
| cfg092.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG092(pem)); |
| cfg092.s.l7urph = 2; |
| cfg092.s.l7utp = 7; |
| cfg092.s.l6urph = 2; |
| cfg092.s.l6utp = 7; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG092(pem), cfg092.u32); |
| /* FIXME: Disable phase 2 and phase 3 equalization */ |
| cfg548.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG548(pem)); |
| cfg548.s.ep2p3d = 1; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG548(pem), cfg548.u32); |
| } |
| /* Errata (GSER-21331) GEN3 Equalization may fail */ |
| /* Disable preset #10 and disable the 2ms timeout */ |
| cfg554.u32 = cvmx_pcie_cfgx_read_node(node, pem, CVMX_PCIERCX_CFG554(pem)); |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) |
| cfg554.s.p23td = 1; |
| cfg554.s.prv = 0x3ff; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG554(pem), cfg554.u32); |
| |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) { |
| need_ep_monitor = (pem_cfg.s.md == 2); |
| if (need_ep_monitor) { |
| cvmx_pciercx_cfg031_t cfg031; |
| cvmx_pciercx_cfg040_t cfg040; |
| |
| /* Force Gen1 for initial link bringup. We'll |
| * fix it later |
| */ |
| pem_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(pem)); |
| pem_cfg.s.md = 0; |
| csr_wr_node(node, CVMX_PEMX_CFG(pem), pem_cfg.u64); |
| cfg031.u32 = cvmx_pcie_cfgx_read_node(node, pem, |
| CVMX_PCIERCX_CFG031(pem)); |
| cfg031.s.mls = 0; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG031(pem), |
| cfg031.u32); |
| cfg040.u32 = cvmx_pcie_cfgx_read_node(node, pem, |
| CVMX_PCIERCX_CFG040(pem)); |
| cfg040.s.tls = 1; |
| cvmx_pcie_cfgx_write_node(node, pem, CVMX_PCIERCX_CFG040(pem), |
| cfg040.u32); |
| __cvmx_qlm_pcie_errata_ep_cn78xx(node, pem); |
| } |
| return; |
| } |
| } |
| |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_0)) { |
| /* De-assert the SOFT_RST bit for this QLM (PEM), causing the PCIe |
| * workarounds code above to take effect. |
| */ |
| soft_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(pem)); |
| soft_prst.s.soft_prst = 0; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(pem), soft_prst.u64); |
| udelay(1); |
| |
| /* Assert the SOFT_RST bit for this QLM (PEM), putting the PCIe back into |
| * reset state with disturbing the workarounds. |
| */ |
| soft_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(pem)); |
| soft_prst.s.soft_prst = 1; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(pem), soft_prst.u64); |
| } |
| udelay(1); |
| } |
| |
| /** |
| * Setup the PEM to either driver or receive reset from PRST based on RC or EP |
| * |
| * @param node Node to use in a Numa setup |
| * @param pem Which PEM to setuo |
| * @param is_endpoint |
| * Non zero if PEM is a EP |
| */ |
| static void __setup_pem_reset(int node, int pem, int is_endpoint) |
| { |
| cvmx_rst_ctlx_t rst_ctl; |
| |
| /* Make sure is_endpoint is either 0 or 1 */ |
| is_endpoint = (is_endpoint != 0); |
| rst_ctl.u64 = csr_rd_node(node, CVMX_RST_CTLX(pem)); |
| rst_ctl.s.prst_link = 0; /* Link down causes soft reset */ |
| rst_ctl.s.rst_link = is_endpoint; /* EP PERST causes a soft reset */ |
| rst_ctl.s.rst_drv = !is_endpoint; /* Drive if RC */ |
| rst_ctl.s.rst_rcv = is_endpoint; /* Only read PERST in EP mode */ |
| rst_ctl.s.rst_chip = 0; /* PERST doesn't pull CHIP_RESET */ |
| csr_wr_node(node, CVMX_RST_CTLX(pem), rst_ctl.u64); |
| } |
| |
| /** |
| * Configure QLM speed and mode for cn78xx. |
| * |
| * @param node Node to configure the QLM |
| * @param qlm The QLM to configure |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP mode. |
| * @param gen3 Only used for PCIe |
| * gen3 = 2 GEN3 mode |
| * gen3 = 1 GEN2 mode |
| * gen3 = 0 GEN1 mode |
| * |
| * @param ref_clk_sel The reference-clock selection to use to configure QLM |
| * 0 = REF_100MHZ |
| * 1 = REF_125MHZ |
| * 2 = REF_156MHZ |
| * 3 = REF_161MHZ |
| * @param ref_clk_input The reference-clock input to use to configure QLM |
| * |
| * @return Return 0 on success or -1. |
| */ |
| int octeon_configure_qlm_cn78xx(int node, int qlm, int baud_mhz, int mode, int rc, int gen3, |
| int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| cvmx_gserx_lane_mode_t lmode; |
| cvmx_gserx_cfg_t cfg; |
| cvmx_gserx_refclk_sel_t refclk_sel; |
| |
| int is_pcie = 0; |
| int is_ilk = 0; |
| int is_bgx = 0; |
| int lane_mode = 0; |
| int lmac_type = 0; |
| bool alt_pll = false; |
| int num_ports = 0; |
| int lane_to_sds = 0; |
| |
| debug("%s(node: %d, qlm: %d, baud_mhz: %d, mode: %d, rc: %d, gen3: %d, ref_clk_sel: %d, ref_clk_input: %d\n", |
| __func__, node, qlm, baud_mhz, mode, rc, gen3, ref_clk_sel, ref_clk_input); |
| if (OCTEON_IS_MODEL(OCTEON_CN76XX) && qlm > 4) { |
| debug("%s: qlm %d not present on CN76XX\n", __func__, qlm); |
| return -1; |
| } |
| |
| /* Errata PEM-31375 PEM RSL accesses to PCLK registers can timeout |
| * during speed change. Change SLI_WINDOW_CTL[time] to 525us |
| */ |
| __set_sli_window_ctl_errata_31375(node); |
| |
| cfg.u64 = csr_rd_node(node, CVMX_GSERX_CFG(qlm)); |
| /* If PEM is in EP, no need to do anything */ |
| |
| if (cfg.s.pcie && rc == 0) { |
| debug("%s: node %d, qlm %d is in PCIe endpoint mode, returning\n", |
| __func__, node, qlm); |
| return 0; |
| } |
| |
| /* Set the reference clock to use */ |
| refclk_sel.u64 = 0; |
| if (ref_clk_input == 0) { /* External ref clock */ |
| refclk_sel.s.com_clk_sel = 0; |
| refclk_sel.s.use_com1 = 0; |
| } else if (ref_clk_input == 1) { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 0; |
| } else { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 1; |
| } |
| |
| csr_wr_node(node, CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| |
| /* Reset the QLM after changing the reference clock */ |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 1; |
| phy_ctl.s.phy_pd = 1; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| udelay(1000); |
| |
| /* Always restore the reference clocks for a QLM */ |
| memcpy(ref_clk_cn78xx[node][qlm], def_ref_clk_cn78xx, sizeof(def_ref_clk_cn78xx)); |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE: |
| case CVMX_QLM_MODE_PCIE_1X8: { |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| |
| is_pcie = 1; |
| |
| if (ref_clk_sel == 0) { |
| refclk_sel.u64 = csr_rd_node(node, CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 0; |
| csr_wr_node(node, CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK100; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK100; |
| else |
| lane_mode = R_8G_REFCLK100; |
| } else if (ref_clk_sel == 1) { |
| refclk_sel.u64 = csr_rd_node(node, CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 1; |
| csr_wr_node(node, CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK125; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK125; |
| else |
| lane_mode = R_8G_REFCLK125; |
| } else { |
| printf("Invalid reference clock for PCIe on QLM%d\n", qlm); |
| return -1; |
| } |
| |
| switch (qlm) { |
| case 0: /* Either x4 or x8 based on PEM0 */ |
| { |
| cvmx_rst_soft_prstx_t rst_prst; |
| |
| rst_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(0)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(0), rst_prst.u64); |
| __setup_pem_reset(node, 0, !rc); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(0)); |
| pemx_cfg.cn78xx.lanes8 = (mode == CVMX_QLM_MODE_PCIE_1X8); |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr_node(node, CVMX_PEMX_CFG(0), pemx_cfg.u64); |
| /* x8 mode waits for QLM1 setup before turning on the PEM */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| } |
| case 1: /* Either PEM0 x8 or PEM1 x4 */ |
| { |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| cvmx_rst_soft_prstx_t rst_prst; |
| cvmx_pemx_cfg_t pemx_cfg; |
| |
| rst_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(1)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(1), rst_prst.u64); |
| __setup_pem_reset(node, 1, !rc); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(1)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr_node(node, CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(1), pemx_on.u64); |
| } else { |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| } |
| case 2: /* Either PEM2 x4 or PEM2 x8 */ |
| { |
| cvmx_rst_soft_prstx_t rst_prst; |
| |
| rst_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(2)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(2), rst_prst.u64); |
| __setup_pem_reset(node, 2, !rc); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(2)); |
| pemx_cfg.cn78xx.lanes8 = (mode == CVMX_QLM_MODE_PCIE_1X8); |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr_node(node, CVMX_PEMX_CFG(2), pemx_cfg.u64); |
| /* x8 mode waits for QLM3 setup before turning on the PEM */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(2)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(2), pemx_on.u64); |
| } |
| break; |
| } |
| case 3: /* Either PEM2 x8 or PEM3 x4 */ |
| { |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(2)); |
| if (pemx_cfg.cn78xx.lanes8) { |
| /* Last 4 lanes of PEM2 */ |
| /* PEMX_CFG already setup */ |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(2)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(2), pemx_on.u64); |
| } |
| /* Check if PEM3 uses QLM3 and in x4 lane mode */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| cvmx_rst_soft_prstx_t rst_prst; |
| |
| rst_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(3)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(3), rst_prst.u64); |
| __setup_pem_reset(node, 3, !rc); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(3)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr_node(node, CVMX_PEMX_CFG(3), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(3)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(3), pemx_on.u64); |
| } |
| break; |
| } |
| case 4: /* Either PEM3 x4 or PEM3 x8 */ |
| { |
| if (mode == CVMX_QLM_MODE_PCIE_1X8) { |
| /* Last 4 lanes of PEM3 */ |
| /* PEMX_CFG already setup */ |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(3)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(3), pemx_on.u64); |
| } else { |
| /* 4 lanes of PEM3 */ |
| cvmx_pemx_qlm_t pemx_qlm; |
| cvmx_rst_soft_prstx_t rst_prst; |
| |
| rst_prst.u64 = csr_rd_node(node, CVMX_RST_SOFT_PRSTX(3)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr_node(node, CVMX_RST_SOFT_PRSTX(3), rst_prst.u64); |
| __setup_pem_reset(node, 3, !rc); |
| |
| pemx_cfg.u64 = csr_rd_node(node, CVMX_PEMX_CFG(3)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr_node(node, CVMX_PEMX_CFG(3), pemx_cfg.u64); |
| /* PEM3 is on QLM4 */ |
| pemx_qlm.u64 = csr_rd_node(node, CVMX_PEMX_QLM(3)); |
| pemx_qlm.cn78xx.pem3qlm = 1; |
| csr_wr_node(node, CVMX_PEMX_QLM(3), pemx_qlm.u64); |
| pemx_on.u64 = csr_rd_node(node, CVMX_PEMX_ON(3)); |
| pemx_on.s.pemon = 1; |
| csr_wr_node(node, CVMX_PEMX_ON(3), pemx_on.u64); |
| } |
| break; |
| } |
| default: |
| break; |
| } |
| break; |
| } |
| case CVMX_QLM_MODE_ILK: |
| is_ilk = 1; |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| if (lane_mode == -1) |
| return -1; |
| /* FIXME: Set lane_mode for other speeds */ |
| break; |
| case CVMX_QLM_MODE_SGMII: |
| is_bgx = 1; |
| lmac_type = 0; |
| lane_to_sds = 1; |
| num_ports = 4; |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| debug("%s: SGMII lane mode: %d, alternate PLL: %s\n", __func__, lane_mode, |
| alt_pll ? "true" : "false"); |
| if (lane_mode == -1) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_XAUI: |
| is_bgx = 5; |
| lmac_type = 1; |
| lane_to_sds = 0xe4; |
| num_ports = 1; |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| debug("%s: XAUI lane mode: %d\n", __func__, lane_mode); |
| if (lane_mode == -1) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_RXAUI: |
| is_bgx = 3; |
| lmac_type = 2; |
| lane_to_sds = 0; |
| num_ports = 2; |
| debug("%s: RXAUI lane mode: %d\n", __func__, lane_mode); |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| if (lane_mode == -1) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_XFI: /* 10GR_4X1 */ |
| case CVMX_QLM_MODE_10G_KR: |
| is_bgx = 1; |
| lmac_type = 3; |
| lane_to_sds = 1; |
| num_ports = 4; |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| debug("%s: XFI/10G_KR lane mode: %d\n", __func__, lane_mode); |
| if (lane_mode == -1) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_XLAUI: /* 40GR4_1X4 */ |
| case CVMX_QLM_MODE_40G_KR4: |
| is_bgx = 5; |
| lmac_type = 4; |
| lane_to_sds = 0xe4; |
| num_ports = 1; |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| debug("%s: XLAUI/40G_KR4 lane mode: %d\n", __func__, lane_mode); |
| if (lane_mode == -1) |
| return -1; |
| break; |
| case CVMX_QLM_MODE_DISABLED: |
| /* Power down the QLM */ |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_pd = 1; |
| phy_ctl.s.phy_reset = 1; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| /* Disable all modes */ |
| csr_wr_node(node, CVMX_GSERX_CFG(qlm), 0); |
| /* Do nothing */ |
| return 0; |
| default: |
| break; |
| } |
| |
| if (alt_pll) { |
| debug("%s: alternate PLL settings used for node %d, qlm %d, lane mode %d, reference clock %d\n", |
| __func__, node, qlm, lane_mode, ref_clk_sel); |
| if (__set_qlm_ref_clk_cn78xx(node, qlm, lane_mode, ref_clk_sel)) { |
| printf("%s: Error: reference clock %d is not supported for node %d, qlm %d\n", |
| __func__, ref_clk_sel, node, qlm); |
| return -1; |
| } |
| } |
| |
| /* Power up PHY, but keep it in reset */ |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_pd = 0; |
| phy_ctl.s.phy_reset = 1; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* Errata GSER-20788: GSER(0..13)_CFG[BGX_QUAD]=1 is broken. Force the |
| * BGX_QUAD bit to be clear for CN78XX pass 1.x |
| */ |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_X)) |
| is_bgx &= 3; |
| |
| /* Set GSER for the interface mode */ |
| cfg.u64 = csr_rd_node(node, CVMX_GSERX_CFG(qlm)); |
| cfg.s.ila = is_ilk; |
| cfg.s.bgx = is_bgx & 1; |
| cfg.s.bgx_quad = (is_bgx >> 2) & 1; |
| cfg.s.bgx_dual = (is_bgx >> 1) & 1; |
| cfg.s.pcie = is_pcie; |
| csr_wr_node(node, CVMX_GSERX_CFG(qlm), cfg.u64); |
| |
| /* Lane mode */ |
| lmode.u64 = csr_rd_node(node, CVMX_GSERX_LANE_MODE(qlm)); |
| lmode.s.lmode = lane_mode; |
| csr_wr_node(node, CVMX_GSERX_LANE_MODE(qlm), lmode.u64); |
| |
| /* BGX0-1 can connect to QLM0-1 or QLM 2-3. Program the select bit if we're |
| * one of these QLMs and we're using BGX |
| */ |
| if (qlm < 4 && is_bgx) { |
| int bgx = qlm & 1; |
| int use_upper = (qlm >> 1) & 1; |
| cvmx_bgxx_cmr_global_config_t global_cfg; |
| |
| global_cfg.u64 = csr_rd_node(node, CVMX_BGXX_CMR_GLOBAL_CONFIG(bgx)); |
| global_cfg.s.pmux_sds_sel = use_upper; |
| csr_wr_node(node, CVMX_BGXX_CMR_GLOBAL_CONFIG(bgx), global_cfg.u64); |
| } |
| |
| /* Bring phy out of reset */ |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 0; |
| csr_wr_node(node, CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| |
| /* |
| * Wait 250 ns until the management interface is ready to accept |
| * read/write commands. |
| */ |
| udelay(1); |
| |
| if (is_bgx) { |
| int bgx = (qlm < 2) ? qlm : qlm - 2; |
| cvmx_bgxx_cmrx_config_t cmr_config; |
| int index; |
| |
| for (index = 0; index < num_ports; index++) { |
| cmr_config.u64 = csr_rd_node(node, CVMX_BGXX_CMRX_CONFIG(index, bgx)); |
| cmr_config.s.enable = 0; |
| cmr_config.s.data_pkt_tx_en = 0; |
| cmr_config.s.data_pkt_rx_en = 0; |
| cmr_config.s.lmac_type = lmac_type; |
| cmr_config.s.lane_to_sds = ((lane_to_sds == 1) ? |
| index : ((lane_to_sds == 0) ? |
| (index ? 0xe : 4) : |
| lane_to_sds)); |
| csr_wr_node(node, CVMX_BGXX_CMRX_CONFIG(index, bgx), cmr_config.u64); |
| } |
| csr_wr_node(node, CVMX_BGXX_CMR_TX_LMACS(bgx), num_ports); |
| csr_wr_node(node, CVMX_BGXX_CMR_RX_LMACS(bgx), num_ports); |
| |
| /* Enable/disable training for 10G_KR/40G_KR4/XFI/XLAUI modes */ |
| for (index = 0; index < num_ports; index++) { |
| cvmx_bgxx_spux_br_pmd_control_t spu_pmd_control; |
| |
| spu_pmd_control.u64 = |
| csr_rd_node(node, CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx)); |
| |
| if (mode == CVMX_QLM_MODE_10G_KR || mode == CVMX_QLM_MODE_40G_KR4) |
| spu_pmd_control.s.train_en = 1; |
| else if (mode == CVMX_QLM_MODE_XFI || mode == CVMX_QLM_MODE_XLAUI) |
| spu_pmd_control.s.train_en = 0; |
| |
| csr_wr_node(node, CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx), |
| spu_pmd_control.u64); |
| } |
| } |
| |
| /* Configure the gser pll */ |
| if (!is_pcie) |
| __qlm_setup_pll_cn78xx(node, qlm); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| if (CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_GSERX_PLL_STAT(qlm), |
| cvmx_gserx_pll_stat_t, |
| pll_lock, ==, 1, 10000)) { |
| printf("%d:QLM%d: Timeout waiting for GSERX_PLL_STAT[pll_lock]\n", |
| node, qlm); |
| return -1; |
| } |
| |
| /* Perform PCIe errata workaround */ |
| if (is_pcie) |
| __cvmx_qlm_pcie_errata_cn78xx(node, qlm); |
| else |
| __qlm_init_errata_20844(node, qlm); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| /* PCIe mode doesn't become ready until the PEM block attempts to bring |
| * the interface up. Skip this check for PCIe |
| */ |
| if (!is_pcie && CVMX_WAIT_FOR_FIELD64_NODE(node, CVMX_GSERX_QLM_STAT(qlm), |
| cvmx_gserx_qlm_stat_t, rst_rdy, |
| ==, 1, 10000)) { |
| printf("%d:QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", |
| node, qlm); |
| return -1; |
| } |
| |
| /* Errata GSER-26150: 10G PHY PLL Temperature Failure */ |
| /* This workaround must be completed after the final deassertion of |
| * GSERx_PHY_CTL[PHY_RESET]. |
| * Apply the workaround to 10.3125Gbps and 8Gbps only. |
| */ |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_X) && |
| (baud_mhz == 103125 || (is_pcie && gen3 == 2))) |
| __qlm_errata_gser_26150(0, qlm, is_pcie); |
| |
| /* Errata GSER-26636: 10G-KR/40G-KR - Inverted Tx Coefficient Direction |
| * Change. Applied to all 10G standards (required for KR) but also |
| * applied to other standards in case software training is used |
| */ |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_X) && baud_mhz == 103125) |
| __qlm_kr_inc_dec_gser26636(node, qlm); |
| |
| /* Errata GSER-25992: RX EQ Default Settings Update (CTLE Bias) */ |
| /* This workaround will only be applied to Pass 1.x */ |
| /* It will also only be applied if the SERDES data-rate is 10G */ |
| /* or if PCIe Gen3 (gen3=2 is PCIe Gen3) */ |
| if (OCTEON_IS_MODEL(OCTEON_CN78XX_PASS1_X) && |
| (baud_mhz == 103125 || (is_pcie && gen3 == 2))) |
| cvmx_qlm_gser_errata_25992(node, qlm); |
| |
| /* Errata GSER-27140: Updating the RX EQ settings due to temperature |
| * drift sensitivities |
| */ |
| /* This workaround will also only be applied if the SERDES data-rate is 10G */ |
| if (baud_mhz == 103125) |
| __qlm_rx_eq_temp_gser27140(node, qlm); |
| |
| /* Reduce the voltage amplitude coming from Marvell PHY and also change |
| * DFE threshold settings for RXAUI interface |
| */ |
| if (is_bgx && mode == CVMX_QLM_MODE_RXAUI) { |
| int l; |
| |
| for (l = 0; l < 4; l++) { |
| cvmx_gserx_lanex_rx_cfg_4_t cfg4; |
| cvmx_gserx_lanex_tx_cfg_0_t cfg0; |
| /* Change the Q/QB error sampler 0 threshold from 0xD to 0xF */ |
| cfg4.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_RX_CFG_4(l, qlm)); |
| cfg4.s.cfg_rx_errdet_ctrl = 0xcf6f; |
| csr_wr_node(node, CVMX_GSERX_LANEX_RX_CFG_4(l, qlm), cfg4.u64); |
| /* Reduce the voltage swing to roughly 460mV */ |
| cfg0.u64 = csr_rd_node(node, CVMX_GSERX_LANEX_TX_CFG_0(l, qlm)); |
| cfg0.s.cfg_tx_swing = 0x12; |
| csr_wr_node(node, CVMX_GSERX_LANEX_TX_CFG_0(l, qlm), cfg0.u64); |
| } |
| } |
| |
| return 0; |
| } |
| |
| static int __is_qlm_valid_bgx_cn73xx(int qlm) |
| { |
| if (qlm == 2 || qlm == 3 || qlm == 5 || qlm == 6) |
| return 0; |
| return 1; |
| } |
| |
| /** |
| * Configure QLM/DLM speed and mode for cn73xx. |
| * |
| * @param qlm The QLM to configure |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP mode. |
| * @param gen3 Only used for PCIe |
| * gen3 = 2 GEN3 mode |
| * gen3 = 1 GEN2 mode |
| * gen3 = 0 GEN1 mode |
| * |
| * @param ref_clk_sel The reference-clock selection to use to configure QLM |
| * 0 = REF_100MHZ |
| * 1 = REF_125MHZ |
| * 2 = REF_156MHZ |
| * 3 = REF_161MHZ |
| * |
| * @param ref_clk_input The reference-clock input to use to configure QLM |
| * 0 = QLM/DLM reference clock input |
| * 1 = common reference clock input 0 |
| * 2 = common reference clock input 1 |
| * |
| * @return Return 0 on success or -1. |
| */ |
| static int octeon_configure_qlm_cn73xx(int qlm, int baud_mhz, int mode, int rc, int gen3, |
| int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| cvmx_gserx_lane_mode_t lmode; |
| cvmx_gserx_cfg_t cfg; |
| cvmx_gserx_refclk_sel_t refclk_sel; |
| int is_pcie = 0; |
| int is_bgx = 0; |
| int lane_mode = 0; |
| short lmac_type[4] = { 0 }; |
| short sds_lane[4] = { 0 }; |
| bool alt_pll = false; |
| int enable_training = 0; |
| int additional_lmacs = 0; |
| |
| debug("%s(qlm: %d, baud_mhz: %d, mode: %d, rc: %d, gen3: %d, ref_clk_sel: %d, ref_clk_input: %d\n", |
| __func__, qlm, baud_mhz, mode, rc, gen3, ref_clk_sel, ref_clk_input); |
| |
| /* Don't configure QLM4 if it is not in SATA mode */ |
| if (qlm == 4) { |
| if (mode == CVMX_QLM_MODE_SATA_2X1) |
| return __setup_sata(qlm, baud_mhz, ref_clk_sel, ref_clk_input); |
| |
| printf("Invalid mode for QLM4\n"); |
| return 0; |
| } |
| |
| cfg.u64 = csr_rd(CVMX_GSERX_CFG(qlm)); |
| |
| /* Errata PEM-31375 PEM RSL accesses to PCLK registers can timeout |
| * during speed change. Change SLI_WINDOW_CTL[time] to 525us |
| */ |
| __set_sli_window_ctl_errata_31375(0); |
| /* If PEM is in EP, no need to do anything */ |
| if (cfg.s.pcie && rc == 0 && |
| (mode == CVMX_QLM_MODE_PCIE || mode == CVMX_QLM_MODE_PCIE_1X8 || |
| mode == CVMX_QLM_MODE_PCIE_1X2)) { |
| debug("%s: qlm %d is in PCIe endpoint mode, returning\n", __func__, qlm); |
| return 0; |
| } |
| |
| /* Set the reference clock to use */ |
| refclk_sel.u64 = 0; |
| if (ref_clk_input == 0) { /* External ref clock */ |
| refclk_sel.s.com_clk_sel = 0; |
| refclk_sel.s.use_com1 = 0; |
| } else if (ref_clk_input == 1) { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 0; |
| } else { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 1; |
| } |
| |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| |
| /* Reset the QLM after changing the reference clock */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 1; |
| phy_ctl.s.phy_pd = 1; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| udelay(1000); |
| |
| /* Check if QLM is a valid BGX interface */ |
| if (mode != CVMX_QLM_MODE_PCIE && mode != CVMX_QLM_MODE_PCIE_1X2 && |
| mode != CVMX_QLM_MODE_PCIE_1X8) { |
| if (__is_qlm_valid_bgx_cn73xx(qlm)) |
| return -1; |
| } |
| |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE: |
| case CVMX_QLM_MODE_PCIE_1X2: |
| case CVMX_QLM_MODE_PCIE_1X8: { |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| cvmx_pemx_qlm_t pemx_qlm; |
| cvmx_rst_soft_prstx_t rst_prst; |
| int port = 0; |
| |
| is_pcie = 1; |
| |
| if (qlm < 5 && mode == CVMX_QLM_MODE_PCIE_1X2) { |
| printf("Invalid PCIe mode(%d) for QLM%d\n", mode, qlm); |
| return -1; |
| } |
| |
| if (ref_clk_sel == 0) { |
| refclk_sel.u64 = csr_rd(CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 0; |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK100; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK100; |
| else |
| lane_mode = R_8G_REFCLK100; |
| } else if (ref_clk_sel == 1) { |
| refclk_sel.u64 = csr_rd(CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 1; |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK125; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK125; |
| else |
| lane_mode = R_8G_REFCLK125; |
| } else { |
| printf("Invalid reference clock for PCIe on QLM%d\n", qlm); |
| return -1; |
| } |
| |
| switch (qlm) { |
| case 0: /* Either x4 or x8 based on PEM0 */ |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(0)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(0), rst_prst.u64); |
| __setup_pem_reset(0, 0, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(0)); |
| pemx_cfg.cn78xx.lanes8 = (mode == CVMX_QLM_MODE_PCIE_1X8); |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(0), pemx_cfg.u64); |
| /* x8 mode waits for QLM1 setup before turning on the PEM */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| case 1: /* Either PEM0 x8 or PEM1 x4 */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(1)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(1), rst_prst.u64); |
| __setup_pem_reset(0, 1, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(1)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(1), pemx_on.u64); |
| } else { /* x8 mode */ |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| case 2: /* Either PEM2 x4 or PEM2 x8 or BGX0 */ |
| { |
| pemx_qlm.u64 = csr_rd(CVMX_PEMX_QLM(2)); |
| pemx_qlm.cn73xx.pemdlmsel = 0; |
| csr_wr(CVMX_PEMX_QLM(2), pemx_qlm.u64); |
| |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(2)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(2), rst_prst.u64); |
| __setup_pem_reset(0, 2, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(2)); |
| pemx_cfg.cn78xx.lanes8 = (mode == CVMX_QLM_MODE_PCIE_1X8); |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(2), pemx_cfg.u64); |
| /* x8 mode waits for QLM3 setup before turning on the PEM */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(2)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(2), pemx_on.u64); |
| } |
| break; |
| } |
| case 3: /* Either PEM2 x8 or PEM3 x4 or BGX1 */ |
| /* PEM2/PEM3 are configured to use QLM2/3 */ |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(2)); |
| if (pemx_cfg.cn78xx.lanes8) { |
| /* Last 4 lanes of PEM2 */ |
| /* PEMX_CFG already setup */ |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(2)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(2), pemx_on.u64); |
| } |
| /* Check if PEM3 uses QLM3 and in x4 lane mode */ |
| if (mode == CVMX_QLM_MODE_PCIE) { |
| pemx_qlm.u64 = csr_rd(CVMX_PEMX_QLM(3)); |
| pemx_qlm.cn73xx.pemdlmsel = 0; |
| csr_wr(CVMX_PEMX_QLM(3), pemx_qlm.u64); |
| |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(3)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(3), rst_prst.u64); |
| __setup_pem_reset(0, 3, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(3)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(3), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(3)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(3), pemx_on.u64); |
| } |
| break; |
| case 5: /* PEM2/PEM3 x2 or BGX2 */ |
| case 6: |
| port = (qlm == 5) ? 2 : 3; |
| if (mode == CVMX_QLM_MODE_PCIE_1X2) { |
| /* PEM2/PEM3 are configured to use DLM5/6 */ |
| pemx_qlm.u64 = csr_rd(CVMX_PEMX_QLM(port)); |
| pemx_qlm.cn73xx.pemdlmsel = 1; |
| csr_wr(CVMX_PEMX_QLM(port), pemx_qlm.u64); |
| /* 2 lanes of PEM3 */ |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(port)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(port), rst_prst.u64); |
| __setup_pem_reset(0, port, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(port)); |
| pemx_cfg.cn78xx.lanes8 = 0; |
| pemx_cfg.cn78xx.hostmd = rc; |
| pemx_cfg.cn78xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(port), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(port)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(port), pemx_on.u64); |
| } |
| break; |
| default: |
| break; |
| } |
| break; |
| } |
| case CVMX_QLM_MODE_SGMII: |
| is_bgx = 1; |
| lmac_type[0] = 0; |
| lmac_type[1] = 0; |
| lmac_type[2] = 0; |
| lmac_type[3] = 0; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| break; |
| case CVMX_QLM_MODE_SGMII_2X1: |
| if (qlm == 5) { |
| is_bgx = 1; |
| lmac_type[0] = 0; |
| lmac_type[1] = 0; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| } else if (qlm == 6) { |
| is_bgx = 1; |
| lmac_type[0] = -1; |
| lmac_type[1] = -1; |
| lmac_type[2] = 0; |
| lmac_type[3] = 0; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| additional_lmacs = 2; |
| } |
| break; |
| case CVMX_QLM_MODE_XAUI: |
| is_bgx = 5; |
| lmac_type[0] = 1; |
| lmac_type[1] = -1; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0xe4; |
| break; |
| case CVMX_QLM_MODE_RXAUI: |
| is_bgx = 3; |
| lmac_type[0] = 2; |
| lmac_type[1] = 2; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0x4; |
| sds_lane[1] = 0xe; |
| break; |
| case CVMX_QLM_MODE_RXAUI_1X2: |
| if (qlm == 5) { |
| is_bgx = 3; |
| lmac_type[0] = 2; |
| lmac_type[1] = -1; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0x4; |
| } |
| if (qlm == 6) { |
| is_bgx = 3; |
| lmac_type[0] = -1; |
| lmac_type[1] = -1; |
| lmac_type[2] = 2; |
| lmac_type[3] = -1; |
| sds_lane[2] = 0xe; |
| additional_lmacs = 2; |
| } |
| break; |
| case CVMX_QLM_MODE_10G_KR: |
| enable_training = 1; |
| case CVMX_QLM_MODE_XFI: /* 10GR_4X1 */ |
| is_bgx = 1; |
| lmac_type[0] = 3; |
| lmac_type[1] = 3; |
| lmac_type[2] = 3; |
| lmac_type[3] = 3; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| break; |
| case CVMX_QLM_MODE_10G_KR_1X2: |
| enable_training = 1; |
| case CVMX_QLM_MODE_XFI_1X2: |
| if (qlm == 5) { |
| is_bgx = 1; |
| lmac_type[0] = 3; |
| lmac_type[1] = 3; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| } else if (qlm == 6) { |
| is_bgx = 1; |
| lmac_type[0] = -1; |
| lmac_type[1] = -1; |
| lmac_type[2] = 3; |
| lmac_type[3] = 3; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| additional_lmacs = 2; |
| } |
| break; |
| case CVMX_QLM_MODE_40G_KR4: |
| enable_training = 1; |
| case CVMX_QLM_MODE_XLAUI: /* 40GR4_1X4 */ |
| is_bgx = 5; |
| lmac_type[0] = 4; |
| lmac_type[1] = -1; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0xe4; |
| break; |
| case CVMX_QLM_MODE_RGMII_SGMII: |
| is_bgx = 1; |
| lmac_type[0] = 5; |
| lmac_type[1] = 0; |
| lmac_type[2] = 0; |
| lmac_type[3] = 0; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| break; |
| case CVMX_QLM_MODE_RGMII_SGMII_1X1: |
| if (qlm == 5) { |
| is_bgx = 1; |
| lmac_type[0] = 5; |
| lmac_type[1] = 0; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| } |
| break; |
| case CVMX_QLM_MODE_RGMII_SGMII_2X1: |
| if (qlm == 6) { |
| is_bgx = 1; |
| lmac_type[0] = 5; |
| lmac_type[1] = -1; |
| lmac_type[2] = 0; |
| lmac_type[3] = 0; |
| sds_lane[0] = 0; |
| sds_lane[2] = 0; |
| sds_lane[3] = 1; |
| } |
| break; |
| case CVMX_QLM_MODE_RGMII_10G_KR: |
| enable_training = 1; |
| case CVMX_QLM_MODE_RGMII_XFI: |
| is_bgx = 1; |
| lmac_type[0] = 5; |
| lmac_type[1] = 3; |
| lmac_type[2] = 3; |
| lmac_type[3] = 3; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| break; |
| case CVMX_QLM_MODE_RGMII_10G_KR_1X1: |
| enable_training = 1; |
| case CVMX_QLM_MODE_RGMII_XFI_1X1: |
| if (qlm == 5) { |
| is_bgx = 3; |
| lmac_type[0] = 5; |
| lmac_type[1] = 3; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| } |
| break; |
| case CVMX_QLM_MODE_RGMII_40G_KR4: |
| enable_training = 1; |
| case CVMX_QLM_MODE_RGMII_XLAUI: |
| is_bgx = 5; |
| lmac_type[0] = 5; |
| lmac_type[1] = 4; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0x0; |
| sds_lane[1] = 0xe4; |
| break; |
| case CVMX_QLM_MODE_RGMII_RXAUI: |
| is_bgx = 3; |
| lmac_type[0] = 5; |
| lmac_type[1] = 2; |
| lmac_type[2] = 2; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0x0; |
| sds_lane[1] = 0x4; |
| sds_lane[2] = 0xe; |
| break; |
| case CVMX_QLM_MODE_RGMII_XAUI: |
| is_bgx = 5; |
| lmac_type[0] = 5; |
| lmac_type[1] = 1; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 0xe4; |
| break; |
| default: |
| break; |
| } |
| |
| if (is_pcie == 0) |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, &alt_pll); |
| debug("%s: %d lane mode: %d, alternate PLL: %s\n", __func__, mode, lane_mode, |
| alt_pll ? "true" : "false"); |
| if (lane_mode == -1) |
| return -1; |
| |
| if (alt_pll) { |
| debug("%s: alternate PLL settings used for qlm %d, lane mode %d, reference clock %d\n", |
| __func__, qlm, lane_mode, ref_clk_sel); |
| if (__set_qlm_ref_clk_cn78xx(0, qlm, lane_mode, ref_clk_sel)) { |
| printf("%s: Error: reference clock %d is not supported for qlm %d, lane mode: 0x%x\n", |
| __func__, ref_clk_sel, qlm, lane_mode); |
| return -1; |
| } |
| } |
| |
| /* Power up PHY, but keep it in reset */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_pd = 0; |
| phy_ctl.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* Set GSER for the interface mode */ |
| cfg.u64 = csr_rd(CVMX_GSERX_CFG(qlm)); |
| cfg.s.bgx = is_bgx & 1; |
| cfg.s.bgx_quad = (is_bgx >> 2) & 1; |
| cfg.s.bgx_dual = (is_bgx >> 1) & 1; |
| cfg.s.pcie = is_pcie; |
| csr_wr(CVMX_GSERX_CFG(qlm), cfg.u64); |
| |
| /* Lane mode */ |
| lmode.u64 = csr_rd(CVMX_GSERX_LANE_MODE(qlm)); |
| lmode.s.lmode = lane_mode; |
| csr_wr(CVMX_GSERX_LANE_MODE(qlm), lmode.u64); |
| |
| /* Program lmac_type to figure out the type of BGX interface configured */ |
| if (is_bgx) { |
| int bgx = (qlm < 4) ? qlm - 2 : 2; |
| cvmx_bgxx_cmrx_config_t cmr_config; |
| cvmx_bgxx_cmr_rx_lmacs_t rx_lmacs; |
| cvmx_bgxx_spux_br_pmd_control_t spu_pmd_control; |
| int index, total_lmacs = 0; |
| |
| for (index = 0; index < 4; index++) { |
| cmr_config.u64 = csr_rd(CVMX_BGXX_CMRX_CONFIG(index, bgx)); |
| cmr_config.s.enable = 0; |
| cmr_config.s.data_pkt_rx_en = 0; |
| cmr_config.s.data_pkt_tx_en = 0; |
| if (lmac_type[index] != -1) { |
| cmr_config.s.lmac_type = lmac_type[index]; |
| cmr_config.s.lane_to_sds = sds_lane[index]; |
| total_lmacs++; |
| /* RXAUI takes up 2 lmacs */ |
| if (lmac_type[index] == 2) |
| total_lmacs += 1; |
| } |
| csr_wr(CVMX_BGXX_CMRX_CONFIG(index, bgx), cmr_config.u64); |
| |
| /* Errata (TBD) RGMII doesn't turn on clock if its by |
| * itself. Force them on |
| */ |
| if (lmac_type[index] == 5) { |
| cvmx_bgxx_cmr_global_config_t global_config; |
| |
| global_config.u64 = csr_rd(CVMX_BGXX_CMR_GLOBAL_CONFIG(bgx)); |
| global_config.s.bgx_clk_enable = 1; |
| csr_wr(CVMX_BGXX_CMR_GLOBAL_CONFIG(bgx), global_config.u64); |
| } |
| |
| /* Enable training for 10G_KR/40G_KR4 modes */ |
| if (enable_training == 1 && |
| (lmac_type[index] == 3 || lmac_type[index] == 4)) { |
| spu_pmd_control.u64 = |
| csr_rd(CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx)); |
| spu_pmd_control.s.train_en = 1; |
| csr_wr(CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx), |
| spu_pmd_control.u64); |
| } |
| } |
| |
| /* Update the total number of lmacs */ |
| rx_lmacs.u64 = csr_rd(CVMX_BGXX_CMR_RX_LMACS(bgx)); |
| rx_lmacs.s.lmacs = total_lmacs + additional_lmacs; |
| csr_wr(CVMX_BGXX_CMR_RX_LMACS(bgx), rx_lmacs.u64); |
| csr_wr(CVMX_BGXX_CMR_TX_LMACS(bgx), rx_lmacs.u64); |
| } |
| |
| /* Bring phy out of reset */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* |
| * Wait 1us until the management interface is ready to accept |
| * read/write commands. |
| */ |
| udelay(1); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| /* PCIe mode doesn't become ready until the PEM block attempts to bring |
| * the interface up. Skip this check for PCIe |
| */ |
| if (!is_pcie && CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_QLM_STAT(qlm), |
| cvmx_gserx_qlm_stat_t, |
| rst_rdy, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", qlm); |
| return -1; |
| } |
| |
| /* Configure the gser pll */ |
| if (!is_pcie) |
| __qlm_setup_pll_cn78xx(0, qlm); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_PLL_STAT(qlm), cvmx_gserx_pll_stat_t, |
| pll_lock, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_PLL_STAT[pll_lock]\n", qlm); |
| return -1; |
| } |
| |
| /* Errata GSER-26150: 10G PHY PLL Temperature Failure */ |
| /* This workaround must be completed after the final deassertion of |
| * GSERx_PHY_CTL[PHY_RESET]. |
| * Apply the workaround to 10.3125Gbps and 8Gbps only. |
| */ |
| if (OCTEON_IS_MODEL(OCTEON_CN73XX_PASS1_0) && |
| (baud_mhz == 103125 || (is_pcie && gen3 == 2))) |
| __qlm_errata_gser_26150(0, qlm, is_pcie); |
| |
| /* Errata GSER-26636: 10G-KR/40G-KR - Inverted Tx Coefficient Direction |
| * Change. Applied to all 10G standards (required for KR) but also |
| * applied to other standards in case software training is used |
| */ |
| if (baud_mhz == 103125) |
| __qlm_kr_inc_dec_gser26636(0, qlm); |
| |
| /* Errata GSER-25992: RX EQ Default Settings Update (CTLE Bias) */ |
| /* This workaround will only be applied to Pass 1.x */ |
| /* It will also only be applied if the SERDES data-rate is 10G */ |
| /* or if PCIe Gen3 (gen3=2 is PCIe Gen3) */ |
| if (baud_mhz == 103125 || (is_pcie && gen3 == 2)) |
| cvmx_qlm_gser_errata_25992(0, qlm); |
| |
| /* Errata GSER-27140: Updating the RX EQ settings due to temperature |
| * drift sensitivities |
| */ |
| /* This workaround will also only be applied if the SERDES data-rate is 10G */ |
| if (baud_mhz == 103125) |
| __qlm_rx_eq_temp_gser27140(0, qlm); |
| |
| /* Reduce the voltage amplitude coming from Marvell PHY and also change |
| * DFE threshold settings for RXAUI interface |
| */ |
| if (is_bgx) { |
| int l; |
| |
| for (l = 0; l < 4; l++) { |
| cvmx_gserx_lanex_rx_cfg_4_t cfg4; |
| cvmx_gserx_lanex_tx_cfg_0_t cfg0; |
| |
| if (lmac_type[l] == 2) { |
| /* Change the Q/QB error sampler 0 threshold from 0xD to 0xF */ |
| cfg4.u64 = csr_rd(CVMX_GSERX_LANEX_RX_CFG_4(l, qlm)); |
| cfg4.s.cfg_rx_errdet_ctrl = 0xcf6f; |
| csr_wr(CVMX_GSERX_LANEX_RX_CFG_4(l, qlm), cfg4.u64); |
| /* Reduce the voltage swing to roughly 460mV */ |
| cfg0.u64 = csr_rd(CVMX_GSERX_LANEX_TX_CFG_0(l, qlm)); |
| cfg0.s.cfg_tx_swing = 0x12; |
| csr_wr(CVMX_GSERX_LANEX_TX_CFG_0(l, qlm), cfg0.u64); |
| } |
| } |
| } |
| |
| return 0; |
| } |
| |
| static int __rmac_pll_config(int baud_mhz, int qlm, int mode) |
| { |
| cvmx_gserx_pll_px_mode_0_t pmode0; |
| cvmx_gserx_pll_px_mode_1_t pmode1; |
| cvmx_gserx_lane_px_mode_0_t lmode0; |
| cvmx_gserx_lane_px_mode_1_t lmode1; |
| cvmx_gserx_lane_mode_t lmode; |
| |
| switch (baud_mhz) { |
| case 98304: |
| pmode0.u64 = 0x1a0a; |
| pmode1.u64 = 0x3228; |
| lmode0.u64 = 0x600f; |
| lmode1.u64 = 0xa80f; |
| break; |
| case 49152: |
| if (mode == CVMX_QLM_MODE_SDL) { |
| pmode0.u64 = 0x3605; |
| pmode1.u64 = 0x0814; |
| lmode0.u64 = 0x000f; |
| lmode1.u64 = 0x6814; |
| } else { |
| pmode0.u64 = 0x1a0a; |
| pmode1.u64 = 0x3228; |
| lmode0.u64 = 0x650f; |
| lmode1.u64 = 0xe80f; |
| } |
| break; |
| case 24576: |
| pmode0.u64 = 0x1a0a; |
| pmode1.u64 = 0x3228; |
| lmode0.u64 = 0x6a0f; |
| lmode1.u64 = 0xe80f; |
| break; |
| case 12288: |
| pmode0.u64 = 0x1a0a; |
| pmode1.u64 = 0x3228; |
| lmode0.u64 = 0x6f0f; |
| lmode1.u64 = 0xe80f; |
| break; |
| case 6144: |
| pmode0.u64 = 0x160a; |
| pmode1.u64 = 0x1019; |
| lmode0.u64 = 0x000f; |
| lmode1.u64 = 0x2814; |
| break; |
| case 3072: |
| pmode0.u64 = 0x160a; |
| pmode1.u64 = 0x1019; |
| lmode0.u64 = 0x050f; |
| lmode1.u64 = 0x6814; |
| break; |
| default: |
| printf("Invalid speed for CPRI/SDL configuration\n"); |
| return -1; |
| } |
| |
| lmode.u64 = csr_rd(CVMX_GSERX_LANE_MODE(qlm)); |
| csr_wr(CVMX_GSERX_PLL_PX_MODE_0(lmode.s.lmode, qlm), pmode0.u64); |
| csr_wr(CVMX_GSERX_PLL_PX_MODE_1(lmode.s.lmode, qlm), pmode1.u64); |
| csr_wr(CVMX_GSERX_LANE_PX_MODE_0(lmode.s.lmode, qlm), lmode0.u64); |
| csr_wr(CVMX_GSERX_LANE_PX_MODE_1(lmode.s.lmode, qlm), lmode1.u64); |
| return 0; |
| } |
| |
| /** |
| * Configure QLM/DLM speed and mode for cnf75xx. |
| * |
| * @param qlm The QLM to configure |
| * @param baud_mhz The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP mode. |
| * @param gen3 Only used for PCIe |
| * gen3 = 2 GEN3 mode |
| * gen3 = 1 GEN2 mode |
| * gen3 = 0 GEN1 mode |
| * |
| * @param ref_clk_sel The reference-clock selection to use to configure QLM |
| * 0 = REF_100MHZ |
| * 1 = REF_125MHZ |
| * 2 = REF_156MHZ |
| * 3 = REF_122MHZ |
| * @param ref_clk_input The reference-clock input to use to configure QLM |
| * |
| * @return Return 0 on success or -1. |
| */ |
| static int octeon_configure_qlm_cnf75xx(int qlm, int baud_mhz, int mode, int rc, int gen3, |
| int ref_clk_sel, int ref_clk_input) |
| { |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| cvmx_gserx_lane_mode_t lmode; |
| cvmx_gserx_cfg_t cfg; |
| cvmx_gserx_refclk_sel_t refclk_sel; |
| int is_pcie = 0; |
| int is_bgx = 0; |
| int is_srio = 0; |
| int is_rmac = 0; |
| int is_rmac_pipe = 0; |
| int lane_mode = 0; |
| short lmac_type[4] = { 0 }; |
| short sds_lane[4] = { 0 }; |
| bool alt_pll = false; |
| int enable_training = 0; |
| int additional_lmacs = 0; |
| int port = (qlm == 3) ? 1 : 0; |
| cvmx_sriox_status_reg_t status_reg; |
| |
| debug("%s(qlm: %d, baud_mhz: %d, mode: %d, rc: %d, gen3: %d, ref_clk_sel: %d, ref_clk_input: %d\n", |
| __func__, qlm, baud_mhz, mode, rc, gen3, ref_clk_sel, ref_clk_input); |
| if (qlm > 8) { |
| printf("Invalid qlm%d passed\n", qlm); |
| return -1; |
| } |
| |
| /* Errata PEM-31375 PEM RSL accesses to PCLK registers can timeout |
| * during speed change. Change SLI_WINDOW_CTL[time] to 525us |
| */ |
| __set_sli_window_ctl_errata_31375(0); |
| |
| cfg.u64 = csr_rd(CVMX_GSERX_CFG(qlm)); |
| |
| /* If PEM is in EP, no need to do anything */ |
| if (cfg.s.pcie && rc == 0) { |
| debug("%s: qlm %d is in PCIe endpoint mode, returning\n", __func__, qlm); |
| return 0; |
| } |
| |
| if (cfg.s.srio && rc == 0) { |
| debug("%s: qlm %d is in SRIO endpoint mode, returning\n", __func__, qlm); |
| return 0; |
| } |
| |
| /* Set the reference clock to use */ |
| refclk_sel.u64 = 0; |
| if (ref_clk_input == 0) { /* External ref clock */ |
| refclk_sel.s.com_clk_sel = 0; |
| refclk_sel.s.use_com1 = 0; |
| } else if (ref_clk_input == 1) { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 0; |
| } else { |
| refclk_sel.s.com_clk_sel = 1; |
| refclk_sel.s.use_com1 = 1; |
| } |
| |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| |
| /* Reset the QLM after changing the reference clock */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 1; |
| phy_ctl.s.phy_pd = 1; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| udelay(1000); |
| |
| switch (mode) { |
| case CVMX_QLM_MODE_PCIE: |
| case CVMX_QLM_MODE_PCIE_1X2: |
| case CVMX_QLM_MODE_PCIE_2X1: { |
| cvmx_pemx_cfg_t pemx_cfg; |
| cvmx_pemx_on_t pemx_on; |
| cvmx_rst_soft_prstx_t rst_prst; |
| |
| is_pcie = 1; |
| |
| if (qlm > 1) { |
| printf("Invalid PCIe mode for QLM%d\n", qlm); |
| return -1; |
| } |
| |
| if (ref_clk_sel == 0) { |
| refclk_sel.u64 = csr_rd(CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 0; |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK100; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK100; |
| else |
| lane_mode = R_8G_REFCLK100; |
| } else if (ref_clk_sel == 1) { |
| refclk_sel.u64 = csr_rd(CVMX_GSERX_REFCLK_SEL(qlm)); |
| refclk_sel.s.pcie_refclk125 = 1; |
| csr_wr(CVMX_GSERX_REFCLK_SEL(qlm), refclk_sel.u64); |
| if (gen3 == 0) /* Gen1 mode */ |
| lane_mode = R_2_5G_REFCLK125; |
| else if (gen3 == 1) /* Gen2 mode */ |
| lane_mode = R_5G_REFCLK125; |
| else |
| lane_mode = R_8G_REFCLK125; |
| } else { |
| printf("Invalid reference clock for PCIe on QLM%d\n", qlm); |
| return -1; |
| } |
| |
| switch (qlm) { |
| case 0: /* Either x4 or x2 based on PEM0 */ |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(0)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(0), rst_prst.u64); |
| __setup_pem_reset(0, 0, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(0)); |
| pemx_cfg.cnf75xx.hostmd = rc; |
| pemx_cfg.cnf75xx.lanes8 = (mode == CVMX_QLM_MODE_PCIE); |
| pemx_cfg.cnf75xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(0), pemx_cfg.u64); |
| /* x4 mode waits for QLM1 setup before turning on the PEM */ |
| if (mode == CVMX_QLM_MODE_PCIE_1X2 || mode == CVMX_QLM_MODE_PCIE_2X1) { |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| case 1: /* Either PEM0 x4 or PEM1 x2 */ |
| if (mode == CVMX_QLM_MODE_PCIE_1X2 || mode == CVMX_QLM_MODE_PCIE_2X1) { |
| rst_prst.u64 = csr_rd(CVMX_RST_SOFT_PRSTX(1)); |
| rst_prst.s.soft_prst = rc; |
| csr_wr(CVMX_RST_SOFT_PRSTX(1), rst_prst.u64); |
| __setup_pem_reset(0, 1, !rc); |
| |
| pemx_cfg.u64 = csr_rd(CVMX_PEMX_CFG(1)); |
| pemx_cfg.cnf75xx.hostmd = rc; |
| pemx_cfg.cnf75xx.md = gen3; |
| csr_wr(CVMX_PEMX_CFG(1), pemx_cfg.u64); |
| |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(1)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(1), pemx_on.u64); |
| } else { |
| pemx_on.u64 = csr_rd(CVMX_PEMX_ON(0)); |
| pemx_on.s.pemon = 1; |
| csr_wr(CVMX_PEMX_ON(0), pemx_on.u64); |
| } |
| break; |
| default: |
| break; |
| } |
| break; |
| } |
| case CVMX_QLM_MODE_SRIO_1X4: |
| case CVMX_QLM_MODE_SRIO_2X2: |
| case CVMX_QLM_MODE_SRIO_4X1: { |
| int spd = 0xf; |
| |
| if (cvmx_fuse_read(1601)) { |
| debug("SRIO is not supported on cnf73xx model\n"); |
| return -1; |
| } |
| |
| switch (baud_mhz) { |
| case 1250: |
| switch (ref_clk_sel) { |
| case 0: /* 100 MHz ref clock */ |
| spd = 0x3; |
| break; |
| case 1: /* 125 MHz ref clock */ |
| spd = 0xa; |
| break; |
| case 2: /* 156.25 MHz ref clock */ |
| spd = 0x4; |
| break; |
| default: |
| spd = 0xf; /* Disabled */ |
| break; |
| } |
| break; |
| case 2500: |
| switch (ref_clk_sel) { |
| case 0: /* 100 MHz ref clock */ |
| spd = 0x2; |
| break; |
| case 1: /* 125 MHz ref clock */ |
| spd = 0x9; |
| break; |
| case 2: /* 156.25 MHz ref clock */ |
| spd = 0x7; |
| break; |
| default: |
| spd = 0xf; /* Disabled */ |
| break; |
| } |
| break; |
| case 3125: |
| switch (ref_clk_sel) { |
| case 1: /* 125 MHz ref clock */ |
| spd = 0x8; |
| break; |
| case 2: /* 156.25 MHz ref clock */ |
| spd = 0xe; |
| break; |
| default: |
| spd = 0xf; /* Disabled */ |
| break; |
| } |
| break; |
| case 5000: |
| switch (ref_clk_sel) { |
| case 0: /* 100 MHz ref clock */ |
| spd = 0x0; |
| break; |
| case 1: /* 125 MHz ref clock */ |
| spd = 0x6; |
| break; |
| case 2: /* 156.25 MHz ref clock */ |
| spd = 0xb; |
| break; |
| default: |
| spd = 0xf; /* Disabled */ |
| break; |
| } |
| break; |
| default: |
| spd = 0xf; |
| break; |
| } |
| |
| if (spd == 0xf) { |
| printf("ERROR: Invalid SRIO speed (%d) configured for QLM%d\n", baud_mhz, |
| qlm); |
| return -1; |
| } |
| |
| status_reg.u64 = csr_rd(CVMX_SRIOX_STATUS_REG(port)); |
| status_reg.s.spd = spd; |
| csr_wr(CVMX_SRIOX_STATUS_REG(port), status_reg.u64); |
| is_srio = 1; |
| break; |
| } |
| |
| case CVMX_QLM_MODE_SGMII_2X1: |
| if (qlm == 4) { |
| is_bgx = 1; |
| lmac_type[0] = 0; |
| lmac_type[1] = 0; |
| lmac_type[2] = -1; |
| lmac_type[3] = -1; |
| sds_lane[0] = 0; |
| sds_lane[1] = 1; |
| } else if (qlm == 5) { |
| is_bgx = 1; |
| lmac_type[0] = -1; |
| lmac_type[1] = -1; |
| lmac_type[2] = 0; |
| lmac_type[3] = 0; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| additional_lmacs = 2; |
| } |
| break; |
| case CVMX_QLM_MODE_10G_KR_1X2: |
| enable_training = 1; |
| case CVMX_QLM_MODE_XFI_1X2: |
| if (qlm == 5) { |
| is_bgx = 1; |
| lmac_type[0] = -1; |
| lmac_type[1] = -1; |
| lmac_type[2] = 3; |
| lmac_type[3] = 3; |
| sds_lane[2] = 2; |
| sds_lane[3] = 3; |
| additional_lmacs = 2; |
| } |
| break; |
| case CVMX_QLM_MODE_CPRI: /* CPRI / JESD204B */ |
| is_rmac = 1; |
| break; |
| case CVMX_QLM_MODE_SDL: /* Serdes Lite (SDL) */ |
| is_rmac = 1; |
| is_rmac_pipe = 1; |
| lane_mode = 1; |
| break; |
| default: |
| break; |
| } |
| |
| if (is_rmac_pipe == 0 && is_pcie == 0) { |
| lane_mode = __get_lane_mode_for_speed_and_ref_clk(ref_clk_sel, baud_mhz, |
| &alt_pll); |
| } |
| |
| debug("%s: %d lane mode: %d, alternate PLL: %s\n", __func__, mode, lane_mode, |
| alt_pll ? "true" : "false"); |
| if (lane_mode == -1) |
| return -1; |
| |
| if (alt_pll) { |
| debug("%s: alternate PLL settings used for qlm %d, lane mode %d, reference clock %d\n", |
| __func__, qlm, lane_mode, ref_clk_sel); |
| if (__set_qlm_ref_clk_cn78xx(0, qlm, lane_mode, ref_clk_sel)) { |
| printf("%s: Error: reference clock %d is not supported for qlm %d\n", |
| __func__, ref_clk_sel, qlm); |
| return -1; |
| } |
| } |
| |
| /* Power up PHY, but keep it in reset */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_pd = 0; |
| phy_ctl.s.phy_reset = 1; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* Set GSER for the interface mode */ |
| cfg.u64 = csr_rd(CVMX_GSERX_CFG(qlm)); |
| cfg.s.bgx = is_bgx & 1; |
| cfg.s.bgx_quad = (is_bgx >> 2) & 1; |
| cfg.s.bgx_dual = (is_bgx >> 1) & 1; |
| cfg.s.pcie = is_pcie; |
| cfg.s.srio = is_srio; |
| cfg.s.rmac = is_rmac; |
| cfg.s.rmac_pipe = is_rmac_pipe; |
| csr_wr(CVMX_GSERX_CFG(qlm), cfg.u64); |
| |
| /* Lane mode */ |
| lmode.u64 = csr_rd(CVMX_GSERX_LANE_MODE(qlm)); |
| lmode.s.lmode = lane_mode; |
| csr_wr(CVMX_GSERX_LANE_MODE(qlm), lmode.u64); |
| |
| /* Because of the Errata where quad mode does not work, program |
| * lmac_type to figure out the type of BGX interface configured |
| */ |
| if (is_bgx) { |
| int bgx = 0; |
| cvmx_bgxx_cmrx_config_t cmr_config; |
| cvmx_bgxx_cmr_rx_lmacs_t rx_lmacs; |
| cvmx_bgxx_spux_br_pmd_control_t spu_pmd_control; |
| int index, total_lmacs = 0; |
| |
| for (index = 0; index < 4; index++) { |
| cmr_config.u64 = csr_rd(CVMX_BGXX_CMRX_CONFIG(index, bgx)); |
| cmr_config.s.enable = 0; |
| cmr_config.s.data_pkt_rx_en = 0; |
| cmr_config.s.data_pkt_tx_en = 0; |
| if (lmac_type[index] != -1) { |
| cmr_config.s.lmac_type = lmac_type[index]; |
| cmr_config.s.lane_to_sds = sds_lane[index]; |
| total_lmacs++; |
| } |
| csr_wr(CVMX_BGXX_CMRX_CONFIG(index, bgx), cmr_config.u64); |
| |
| /* Enable training for 10G_KR/40G_KR4 modes */ |
| if (enable_training == 1 && |
| (lmac_type[index] == 3 || lmac_type[index] == 4)) { |
| spu_pmd_control.u64 = |
| csr_rd(CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx)); |
| spu_pmd_control.s.train_en = 1; |
| csr_wr(CVMX_BGXX_SPUX_BR_PMD_CONTROL(index, bgx), |
| spu_pmd_control.u64); |
| } |
| } |
| |
| /* Update the total number of lmacs */ |
| rx_lmacs.u64 = csr_rd(CVMX_BGXX_CMR_RX_LMACS(bgx)); |
| rx_lmacs.s.lmacs = total_lmacs + additional_lmacs; |
| csr_wr(CVMX_BGXX_CMR_RX_LMACS(bgx), rx_lmacs.u64); |
| csr_wr(CVMX_BGXX_CMR_TX_LMACS(bgx), rx_lmacs.u64); |
| } |
| |
| /* Bring phy out of reset */ |
| phy_ctl.u64 = csr_rd(CVMX_GSERX_PHY_CTL(qlm)); |
| phy_ctl.s.phy_reset = 0; |
| csr_wr(CVMX_GSERX_PHY_CTL(qlm), phy_ctl.u64); |
| |
| /* |
| * Wait 1us until the management interface is ready to accept |
| * read/write commands. |
| */ |
| udelay(1); |
| |
| if (is_srio) { |
| status_reg.u64 = csr_rd(CVMX_SRIOX_STATUS_REG(port)); |
| status_reg.s.srio = 1; |
| csr_wr(CVMX_SRIOX_STATUS_REG(port), status_reg.u64); |
| return 0; |
| } |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| /* PCIe mode doesn't become ready until the PEM block attempts to bring |
| * the interface up. Skip this check for PCIe |
| */ |
| if (!is_pcie && CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_QLM_STAT(qlm), cvmx_gserx_qlm_stat_t, |
| rst_rdy, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_QLM_STAT[rst_rdy]\n", qlm); |
| return -1; |
| } |
| |
| /* Configure the gser pll */ |
| if (is_rmac) |
| __rmac_pll_config(baud_mhz, qlm, mode); |
| else if (!(is_pcie || is_srio)) |
| __qlm_setup_pll_cn78xx(0, qlm); |
| |
| /* Wait for reset to complete and the PLL to lock */ |
| if (CVMX_WAIT_FOR_FIELD64(CVMX_GSERX_PLL_STAT(qlm), cvmx_gserx_pll_stat_t, |
| pll_lock, ==, 1, 10000)) { |
| printf("QLM%d: Timeout waiting for GSERX_PLL_STAT[pll_lock]\n", qlm); |
| return -1; |
| } |
| |
| /* Errata GSER-27140: Updating the RX EQ settings due to temperature |
| * drift sensitivities |
| */ |
| /* This workaround will also only be applied if the SERDES data-rate is 10G */ |
| if (baud_mhz == 103125) |
| __qlm_rx_eq_temp_gser27140(0, qlm); |
| |
| return 0; |
| } |
| |
| /** |
| * Configure qlm/dlm speed and mode. |
| * @param qlm The QLM or DLM to configure |
| * @param speed The speed the QLM needs to be configured in Mhz. |
| * @param mode The QLM to be configured as SGMII/XAUI/PCIe. |
| * @param rc Only used for PCIe, rc = 1 for root complex mode, 0 for EP |
| * mode. |
| * @param pcie_mode Only used when qlm/dlm are in pcie mode. |
| * @param ref_clk_sel Reference clock to use for 70XX where: |
| * 0: 100MHz |
| * 1: 125MHz |
| * 2: 156.25MHz |
| * 3: 122MHz (Used by RMAC) |
| * @param ref_clk_input This selects which reference clock input to use. For |
| * cn70xx: |
| * 0: DLMC_REF_CLK0 |
| * 1: DLMC_REF_CLK1 |
| * 2: DLM0_REF_CLK |
| * cn61xx: (not used) |
| * cn78xx/cn76xx/cn73xx: |
| * 0: Internal clock (QLM[0-7]_REF_CLK) |
| * 1: QLMC_REF_CLK0 |
| * 2: QLMC_REF_CLK1 |
| * |
| * @return Return 0 on success or -1. |
| */ |
| int octeon_configure_qlm(int qlm, int speed, int mode, int rc, int pcie_mode, int ref_clk_sel, |
| int ref_clk_input) |
| { |
| int node = 0; // ToDo: corrently only node 0 is supported |
| |
| debug("%s(%d, %d, %d, %d, %d, %d, %d)\n", __func__, qlm, speed, mode, rc, pcie_mode, |
| ref_clk_sel, ref_clk_input); |
| if (OCTEON_IS_MODEL(OCTEON_CN61XX) || OCTEON_IS_MODEL(OCTEON_CNF71XX)) |
| return octeon_configure_qlm_cn61xx(qlm, speed, mode, rc, pcie_mode); |
| else if (OCTEON_IS_MODEL(OCTEON_CN70XX)) |
| return octeon_configure_qlm_cn70xx(qlm, speed, mode, rc, pcie_mode, ref_clk_sel, |
| ref_clk_input); |
| else if (OCTEON_IS_MODEL(OCTEON_CN78XX)) |
| return octeon_configure_qlm_cn78xx(node, qlm, speed, mode, rc, pcie_mode, |
| ref_clk_sel, ref_clk_input); |
| else if (OCTEON_IS_MODEL(OCTEON_CN73XX)) |
| return octeon_configure_qlm_cn73xx(qlm, speed, mode, rc, pcie_mode, ref_clk_sel, |
| ref_clk_input); |
| else if (OCTEON_IS_MODEL(OCTEON_CNF75XX)) |
| return octeon_configure_qlm_cnf75xx(qlm, speed, mode, rc, pcie_mode, ref_clk_sel, |
| ref_clk_input); |
| else |
| return -1; |
| } |
| |
| void octeon_init_qlm(int node) |
| { |
| int qlm; |
| cvmx_gserx_phy_ctl_t phy_ctl; |
| cvmx_gserx_cfg_t cfg; |
| int baud_mhz; |
| int pem; |
| |
| if (!OCTEON_IS_MODEL(OCTEON_CN78XX)) |
| return; |
| |
| for (qlm = 0; qlm < 8; qlm++) { |
| phy_ctl.u64 = csr_rd_node(node, CVMX_GSERX_PHY_CTL(qlm)); |
| if (phy_ctl.s.phy_reset == 0) { |
| cfg.u64 = csr_rd_node(node, CVMX_GSERX_CFG(qlm)); |
| if (cfg.s.pcie) |
| __cvmx_qlm_pcie_errata_cn78xx(node, qlm); |
| else |
| __qlm_init_errata_20844(node, qlm); |
| |
| baud_mhz = cvmx_qlm_get_gbaud_mhz_node(node, qlm); |
| if (baud_mhz == 6250 || baud_mhz == 6316) |
| octeon_qlm_tune_v3(node, qlm, baud_mhz, 0xa, 0xa0, -1, -1); |
| else if (baud_mhz == 103125) |
| octeon_qlm_tune_v3(node, qlm, baud_mhz, 0xd, 0xd0, -1, -1); |
| } |
| } |
| |
| /* Setup how each PEM drives the PERST lines */ |
| for (pem = 0; pem < 4; pem++) { |
| cvmx_rst_ctlx_t rst_ctl; |
| |
| rst_ctl.u64 = csr_rd_node(node, CVMX_RST_CTLX(pem)); |
| __setup_pem_reset(node, pem, !rst_ctl.s.host_mode); |
| } |
| } |