// SPDX-License-Identifier: GPL-2.0+ /* * TI serdes driver for keystone2. * * (C) Copyright 2014 * Texas Instruments Incorporated, */ #include #include #include #include #include #define SERDES_CMU_REGS(x) (0x0000 + (0x0c00 * (x))) #define SERDES_LANE_REGS(x) (0x0200 + (0x200 * (x))) #define SERDES_COMLANE_REGS 0x0a00 #define SERDES_WIZ_REGS 0x1fc0 #define SERDES_CMU_REG_000(x) (SERDES_CMU_REGS(x) + 0x000) #define SERDES_CMU_REG_010(x) (SERDES_CMU_REGS(x) + 0x010) #define SERDES_COMLANE_REG_000 (SERDES_COMLANE_REGS + 0x000) #define SERDES_LANE_REG_000(x) (SERDES_LANE_REGS(x) + 0x000) #define SERDES_LANE_REG_028(x) (SERDES_LANE_REGS(x) + 0x028) #define SERDES_LANE_CTL_STATUS_REG(x) (SERDES_WIZ_REGS + 0x0020 + (4 * (x))) #define SERDES_PLL_CTL_REG (SERDES_WIZ_REGS + 0x0034) #define SERDES_RESET BIT(28) #define SERDES_LANE_RESET BIT(29) #define SERDES_LANE_LOOPBACK BIT(30) #define SERDES_LANE_EN_VAL(x, y, z) (x[y] | (z << 26) | (z << 10)) #define SERDES_CMU_CFG_NUM 5 #define SERDES_COMLANE_CFG_NUM 10 #define SERDES_LANE_CFG_NUM 10 struct serdes_cfg { u32 ofs; u32 val; u32 mask; }; struct cfg_entry { enum ks2_serdes_clock clk; enum ks2_serdes_rate rate; struct serdes_cfg cmu[SERDES_CMU_CFG_NUM]; struct serdes_cfg comlane[SERDES_COMLANE_CFG_NUM]; struct serdes_cfg lane[SERDES_LANE_CFG_NUM]; }; /* SERDES PHY lane enable configuration value, indexed by PHY interface */ static u32 serdes_cfg_lane_enable[] = { 0xf000f0c0, /* SGMII */ 0xf0e9f038, /* PCSR */ }; /* SERDES PHY PLL enable configuration value, indexed by PHY interface */ static u32 serdes_cfg_pll_enable[] = { 0xe0000000, /* SGMII */ 0xee000000, /* PCSR */ }; /** * Array to hold all possible serdes configurations. * Combination for 5 clock settings and 6 baud rates. */ static struct cfg_entry cfgs[] = { { .clk = SERDES_CLOCK_156P25M, .rate = SERDES_RATE_5G, .cmu = { {0x0000, 0x00800000, 0xffff0000}, {0x0014, 0x00008282, 0x0000ffff}, {0x0060, 0x00142438, 0x00ffffff}, {0x0064, 0x00c3c700, 0x00ffff00}, {0x0078, 0x0000c000, 0x0000ff00} }, .comlane = { {0x0a00, 0x00000800, 0x0000ff00}, {0x0a08, 0x38a20000, 0xffff0000}, {0x0a30, 0x008a8a00, 0x00ffff00}, {0x0a84, 0x00000600, 0x0000ff00}, {0x0a94, 0x10000000, 0xff000000}, {0x0aa0, 0x81000000, 0xff000000}, {0x0abc, 0xff000000, 0xff000000}, {0x0ac0, 0x0000008b, 0x000000ff}, {0x0b08, 0x583f0000, 0xffff0000}, {0x0b0c, 0x0000004e, 0x000000ff} }, .lane = { {0x0004, 0x38000080, 0xff0000ff}, {0x0008, 0x00000000, 0x000000ff}, {0x000c, 0x02000000, 0xff000000}, {0x0010, 0x1b000000, 0xff000000}, {0x0014, 0x00006fb8, 0x0000ffff}, {0x0018, 0x758000e4, 0xffff00ff}, {0x00ac, 0x00004400, 0x0000ff00}, {0x002c, 0x00100800, 0x00ffff00}, {0x0080, 0x00820082, 0x00ff00ff}, {0x0084, 0x1d0f0385, 0xffffffff} }, }, }; static inline void ks2_serdes_rmw(u32 addr, u32 value, u32 mask) { writel(((readl(addr) & (~mask)) | (value & mask)), addr); } static void ks2_serdes_cfg_setup(u32 base, struct serdes_cfg *cfg, u32 size) { u32 i; for (i = 0; i < size; i++) ks2_serdes_rmw(base + cfg[i].ofs, cfg[i].val, cfg[i].mask); } static void ks2_serdes_lane_config(u32 base, struct serdes_cfg *cfg_lane, u32 size, u32 lane) { u32 i; for (i = 0; i < size; i++) ks2_serdes_rmw(base + cfg_lane[i].ofs + SERDES_LANE_REGS(lane), cfg_lane[i].val, cfg_lane[i].mask); } static int ks2_serdes_init_cfg(u32 base, struct cfg_entry *cfg, u32 num_lanes) { u32 i; ks2_serdes_cfg_setup(base, cfg->cmu, SERDES_CMU_CFG_NUM); ks2_serdes_cfg_setup(base, cfg->comlane, SERDES_COMLANE_CFG_NUM); for (i = 0; i < num_lanes; i++) ks2_serdes_lane_config(base, cfg->lane, SERDES_LANE_CFG_NUM, i); return 0; } static void ks2_serdes_cmu_comlane_enable(u32 base, struct ks2_serdes *serdes) { /* Bring SerDes out of Reset */ ks2_serdes_rmw(base + SERDES_CMU_REG_010(0), 0x0, SERDES_RESET); if (serdes->intf == SERDES_PHY_PCSR) ks2_serdes_rmw(base + SERDES_CMU_REG_010(1), 0x0, SERDES_RESET); /* Enable CMU and COMLANE */ ks2_serdes_rmw(base + SERDES_CMU_REG_000(0), 0x03, 0x000000ff); if (serdes->intf == SERDES_PHY_PCSR) ks2_serdes_rmw(base + SERDES_CMU_REG_000(1), 0x03, 0x000000ff); ks2_serdes_rmw(base + SERDES_COMLANE_REG_000, 0x5f, 0x000000ff); } static void ks2_serdes_pll_enable(u32 base, struct ks2_serdes *serdes) { writel(serdes_cfg_pll_enable[serdes->intf], base + SERDES_PLL_CTL_REG); } static void ks2_serdes_lane_reset(u32 base, u32 reset, u32 lane) { if (reset) ks2_serdes_rmw(base + SERDES_LANE_REG_028(lane), 0x1, SERDES_LANE_RESET); else ks2_serdes_rmw(base + SERDES_LANE_REG_028(lane), 0x0, SERDES_LANE_RESET); } static void ks2_serdes_lane_enable(u32 base, struct ks2_serdes *serdes, u32 lane) { /* Bring lane out of reset */ ks2_serdes_lane_reset(base, 0, lane); writel(SERDES_LANE_EN_VAL(serdes_cfg_lane_enable, serdes->intf, serdes->rate_mode), base + SERDES_LANE_CTL_STATUS_REG(lane)); /* Set NES bit if Loopback Enabled */ if (serdes->loopback) ks2_serdes_rmw(base + SERDES_LANE_REG_000(lane), 0x1, SERDES_LANE_LOOPBACK); } int ks2_serdes_init(u32 base, struct ks2_serdes *serdes, u32 num_lanes) { int i; int ret = 0; for (i = 0; i < ARRAY_SIZE(cfgs); i++) if (serdes->clk == cfgs[i].clk && serdes->rate == cfgs[i].rate) break; if (i >= ARRAY_SIZE(cfgs)) { puts("Cannot find keystone SerDes configuration"); return -EINVAL; } ks2_serdes_init_cfg(base, &cfgs[i], num_lanes); ks2_serdes_cmu_comlane_enable(base, serdes); for (i = 0; i < num_lanes; i++) ks2_serdes_lane_enable(base, serdes, i); ks2_serdes_pll_enable(base, serdes); return ret; }