/* * clock_ti814x.c * * Clocks for TI814X based boards * * Copyright (C) 2013, Texas Instruments, Incorporated * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include #include /* PRCM */ #define PRCM_MOD_EN 0x2 /* CLK_SRC */ #define OSC_SRC0 0 #define OSC_SRC1 1 #define L3_OSC_SRC OSC_SRC0 #define OSC_0_FREQ 20 #define DCO_HS2_MIN 500 #define DCO_HS2_MAX 1000 #define DCO_HS1_MIN 1000 #define DCO_HS1_MAX 2000 #define SELFREQDCO_HS2 0x00000801 #define SELFREQDCO_HS1 0x00001001 #define MPU_N 0x1 #define MPU_M 0x3C #define MPU_M2 1 #define MPU_CLKCTRL 0x1 #define L3_N 19 #define L3_M 880 #define L3_M2 4 #define L3_CLKCTRL 0x801 #define DDR_N 19 #define DDR_M 666 #define DDR_M2 2 #define DDR_CLKCTRL 0x801 /* ADPLLJ register values */ #define ADPLLJ_CLKCTRL_HS2 0x00000801 /* HS2 mode, TINT2 = 1 */ #define ADPLLJ_CLKCTRL_HS1 0x00001001 /* HS1 mode, TINT2 = 1 */ #define ADPLLJ_CLKCTRL_CLKDCOLDOEN (1 << 29) #define ADPLLJ_CLKCTRL_IDLE (1 << 23) #define ADPLLJ_CLKCTRL_CLKOUTEN (1 << 20) #define ADPLLJ_CLKCTRL_CLKOUTLDOEN (1 << 19) #define ADPLLJ_CLKCTRL_CLKDCOLDOPWDNZ (1 << 17) #define ADPLLJ_CLKCTRL_LPMODE (1 << 12) #define ADPLLJ_CLKCTRL_DRIFTGUARDIAN (1 << 11) #define ADPLLJ_CLKCTRL_REGM4XEN (1 << 10) #define ADPLLJ_CLKCTRL_TINITZ (1 << 0) #define ADPLLJ_CLKCTRL_CLKDCO (ADPLLJ_CLKCTRL_CLKDCOLDOEN | \ ADPLLJ_CLKCTRL_CLKOUTEN | \ ADPLLJ_CLKCTRL_CLKOUTLDOEN | \ ADPLLJ_CLKCTRL_CLKDCOLDOPWDNZ) #define ADPLLJ_STATUS_PHASELOCK (1 << 10) #define ADPLLJ_STATUS_FREQLOCK (1 << 9) #define ADPLLJ_STATUS_PHSFRQLOCK (ADPLLJ_STATUS_PHASELOCK | \ ADPLLJ_STATUS_FREQLOCK) #define ADPLLJ_STATUS_BYPASSACK (1 << 8) #define ADPLLJ_STATUS_BYPASS (1 << 0) #define ADPLLJ_STATUS_BYPASSANDACK (ADPLLJ_STATUS_BYPASSACK | \ ADPLLJ_STATUS_BYPASS) #define ADPLLJ_TENABLE_ENB (1 << 0) #define ADPLLJ_TENABLEDIV_ENB (1 << 0) #define ADPLLJ_M2NDIV_M2SHIFT 16 #define MPU_PLL_BASE (PLL_SUBSYS_BASE + 0x048) #define L3_PLL_BASE (PLL_SUBSYS_BASE + 0x110) #define DDR_PLL_BASE (PLL_SUBSYS_BASE + 0x290) struct ad_pll { unsigned int pwrctrl; unsigned int clkctrl; unsigned int tenable; unsigned int tenablediv; unsigned int m2ndiv; unsigned int mn2div; unsigned int fracdiv; unsigned int bwctrl; unsigned int fracctrl; unsigned int status; unsigned int m3div; unsigned int rampctrl; }; #define OSC_SRC_CTRL (PLL_SUBSYS_BASE + 0x2C0) #define ENET_CLKCTRL_CMPL 0x30000 #define SATA_PLL_BASE (CTRL_BASE + 0x0720) struct sata_pll { unsigned int pllcfg0; unsigned int pllcfg1; unsigned int pllcfg2; unsigned int pllcfg3; unsigned int pllcfg4; unsigned int pllstatus; unsigned int rxstatus; unsigned int txstatus; unsigned int testcfg; }; #define SEL_IN_FREQ (0x1 << 31) #define DIGCLRZ (0x1 << 30) #define ENDIGLDO (0x1 << 4) #define APLL_CP_CURR (0x1 << 3) #define ENBGSC_REF (0x1 << 2) #define ENPLLLDO (0x1 << 1) #define ENPLL (0x1 << 0) #define SATA_PLLCFG0_1 (SEL_IN_FREQ | ENBGSC_REF) #define SATA_PLLCFG0_2 (SEL_IN_FREQ | ENDIGLDO | ENBGSC_REF) #define SATA_PLLCFG0_3 (SEL_IN_FREQ | ENDIGLDO | ENBGSC_REF | ENPLLLDO) #define SATA_PLLCFG0_4 (SEL_IN_FREQ | DIGCLRZ | ENDIGLDO | ENBGSC_REF | \ ENPLLLDO | ENPLL) #define PLL_LOCK (0x1 << 0) #define ENSATAMODE (0x1 << 31) #define PLLREFSEL (0x1 << 30) #define MDIVINT (0x4b << 18) #define EN_CLKAUX (0x1 << 5) #define EN_CLK125M (0x1 << 4) #define EN_CLK100M (0x1 << 3) #define EN_CLK50M (0x1 << 2) #define SATA_PLLCFG1 (ENSATAMODE | \ PLLREFSEL | \ MDIVINT | \ EN_CLKAUX | \ EN_CLK125M | \ EN_CLK100M | \ EN_CLK50M) #define DIGLDO_EN_CAPLESSMODE (0x1 << 22) #define PLLDO_EN_LDO_STABLE (0x1 << 11) #define PLLDO_EN_BUF_CUR (0x1 << 7) #define PLLDO_EN_LP (0x1 << 6) #define PLLDO_CTRL_TRIM_1_4V (0x10 << 1) #define SATA_PLLCFG3 (DIGLDO_EN_CAPLESSMODE | \ PLLDO_EN_LDO_STABLE | \ PLLDO_EN_BUF_CUR | \ PLLDO_EN_LP | \ PLLDO_CTRL_TRIM_1_4V) const struct cm_alwon *cmalwon = (struct cm_alwon *)CM_ALWON_BASE; const struct cm_def *cmdef = (struct cm_def *)CM_DEFAULT_BASE; const struct sata_pll *spll = (struct sata_pll *)SATA_PLL_BASE; /* * Enable the peripheral clock for required peripherals */ static void enable_per_clocks(void) { /* HSMMC1 */ writel(PRCM_MOD_EN, &cmalwon->mmchs1clkctrl); while (readl(&cmalwon->mmchs1clkctrl) != PRCM_MOD_EN) ; /* Ethernet */ writel(PRCM_MOD_EN, &cmalwon->ethclkstctrl); writel(PRCM_MOD_EN, &cmalwon->ethernet0clkctrl); while ((readl(&cmalwon->ethernet0clkctrl) & ENET_CLKCTRL_CMPL) != 0) ; writel(PRCM_MOD_EN, &cmalwon->ethernet1clkctrl); while ((readl(&cmalwon->ethernet1clkctrl) & ENET_CLKCTRL_CMPL) != 0) ; /* RTC clocks */ writel(PRCM_MOD_EN, &cmalwon->rtcclkstctrl); writel(PRCM_MOD_EN, &cmalwon->rtcclkctrl); while (readl(&cmalwon->rtcclkctrl) != PRCM_MOD_EN) ; } /* * select the HS1 or HS2 for DCO Freq * return : CLKCTRL */ static u32 pll_dco_freq_sel(u32 clkout_dco) { if (clkout_dco >= DCO_HS2_MIN && clkout_dco < DCO_HS2_MAX) return SELFREQDCO_HS2; else if (clkout_dco >= DCO_HS1_MIN && clkout_dco < DCO_HS1_MAX) return SELFREQDCO_HS1; else return -1; } /* * select the sigma delta config * return: sigma delta val */ static u32 pll_sigma_delta_val(u32 clkout_dco) { u32 sig_val = 0; sig_val = (clkout_dco + 225) / 250; sig_val = sig_val << 24; return sig_val; } /* * configure individual ADPLLJ */ static void pll_config(u32 base, u32 n, u32 m, u32 m2, u32 clkctrl_val, int adpllj) { const struct ad_pll *adpll = (struct ad_pll *)base; u32 m2nval, mn2val, read_clkctrl = 0, clkout_dco = 0; u32 sig_val = 0, hs_mod = 0; m2nval = (m2 << ADPLLJ_M2NDIV_M2SHIFT) | n; mn2val = m; /* calculate clkout_dco */ clkout_dco = ((OSC_0_FREQ / (n+1)) * m); /* sigma delta & Hs mode selection skip for ADPLLS*/ if (adpllj) { sig_val = pll_sigma_delta_val(clkout_dco); hs_mod = pll_dco_freq_sel(clkout_dco); } /* by-pass pll */ read_clkctrl = readl(&adpll->clkctrl); writel((read_clkctrl | ADPLLJ_CLKCTRL_IDLE), &adpll->clkctrl); while ((readl(&adpll->status) & ADPLLJ_STATUS_BYPASSANDACK) != ADPLLJ_STATUS_BYPASSANDACK) ; /* clear TINITZ */ read_clkctrl = readl(&adpll->clkctrl); writel((read_clkctrl & ~ADPLLJ_CLKCTRL_TINITZ), &adpll->clkctrl); /* * ref_clk = 20/(n + 1); * clkout_dco = ref_clk * m; * clk_out = clkout_dco/m2; */ read_clkctrl = readl(&adpll->clkctrl) & ~(ADPLLJ_CLKCTRL_LPMODE | ADPLLJ_CLKCTRL_DRIFTGUARDIAN | ADPLLJ_CLKCTRL_REGM4XEN); writel(m2nval, &adpll->m2ndiv); writel(mn2val, &adpll->mn2div); /* Skip for modena(ADPLLS) */ if (adpllj) { writel(sig_val, &adpll->fracdiv); writel((read_clkctrl | hs_mod), &adpll->clkctrl); } /* Load M2, N2 dividers of ADPLL */ writel(ADPLLJ_TENABLEDIV_ENB, &adpll->tenablediv); writel(~ADPLLJ_TENABLEDIV_ENB, &adpll->tenablediv); /* Load M, N dividers of ADPLL */ writel(ADPLLJ_TENABLE_ENB, &adpll->tenable); writel(~ADPLLJ_TENABLE_ENB, &adpll->tenable); /* Configure CLKDCOLDOEN,CLKOUTLDOEN,CLKOUT Enable BITS */ read_clkctrl = readl(&adpll->clkctrl) & ~ADPLLJ_CLKCTRL_CLKDCO; if (adpllj) writel((read_clkctrl | ADPLLJ_CLKCTRL_CLKDCO), &adpll->clkctrl); /* Enable TINTZ and disable IDLE(PLL in Active & Locked Mode */ read_clkctrl = readl(&adpll->clkctrl) & ~ADPLLJ_CLKCTRL_IDLE; writel((read_clkctrl | ADPLLJ_CLKCTRL_TINITZ), &adpll->clkctrl); /* Wait for phase and freq lock */ while ((readl(&adpll->status) & ADPLLJ_STATUS_PHSFRQLOCK) != ADPLLJ_STATUS_PHSFRQLOCK) ; } static void unlock_pll_control_mmr(void) { /* TRM 2.10.1.4 and 3.2.7-3.2.11 */ writel(0x1EDA4C3D, 0x481C5040); writel(0x2FF1AC2B, 0x48140060); writel(0xF757FDC0, 0x48140064); writel(0xE2BC3A6D, 0x48140068); writel(0x1EBF131D, 0x4814006c); writel(0x6F361E05, 0x48140070); } static void mpu_pll_config(void) { pll_config(MPU_PLL_BASE, MPU_N, MPU_M, MPU_M2, MPU_CLKCTRL, 0); } static void l3_pll_config(void) { u32 l3_osc_src, rd_osc_src = 0; l3_osc_src = L3_OSC_SRC; rd_osc_src = readl(OSC_SRC_CTRL); if (OSC_SRC0 == l3_osc_src) writel((rd_osc_src & 0xfffffffe)|0x0, OSC_SRC_CTRL); else writel((rd_osc_src & 0xfffffffe)|0x1, OSC_SRC_CTRL); pll_config(L3_PLL_BASE, L3_N, L3_M, L3_M2, L3_CLKCTRL, 1); } void ddr_pll_config(unsigned int ddrpll_m) { pll_config(DDR_PLL_BASE, DDR_N, DDR_M, DDR_M2, DDR_CLKCTRL, 1); } void sata_pll_config(void) { /* * This sequence for configuring the SATA PLL * resident in the control module is documented * in TI8148 TRM section 21.3.1 */ writel(SATA_PLLCFG1, &spll->pllcfg1); udelay(50); writel(SATA_PLLCFG3, &spll->pllcfg3); udelay(50); writel(SATA_PLLCFG0_1, &spll->pllcfg0); udelay(50); writel(SATA_PLLCFG0_2, &spll->pllcfg0); udelay(50); writel(SATA_PLLCFG0_3, &spll->pllcfg0); udelay(50); writel(SATA_PLLCFG0_4, &spll->pllcfg0); udelay(50); while (((readl(&spll->pllstatus) & PLL_LOCK) == 0)) ; } void enable_dmm_clocks(void) { writel(PRCM_MOD_EN, &cmdef->fwclkctrl); writel(PRCM_MOD_EN, &cmdef->l3fastclkstctrl); writel(PRCM_MOD_EN, &cmdef->emif0clkctrl); while ((readl(&cmdef->emif0clkctrl)) != PRCM_MOD_EN) ; writel(PRCM_MOD_EN, &cmdef->emif1clkctrl); while ((readl(&cmdef->emif1clkctrl)) != PRCM_MOD_EN) ; while ((readl(&cmdef->l3fastclkstctrl) & 0x300) != 0x300) ; writel(PRCM_MOD_EN, &cmdef->dmmclkctrl); while ((readl(&cmdef->dmmclkctrl)) != PRCM_MOD_EN) ; writel(PRCM_MOD_EN, &cmalwon->l3slowclkstctrl); while ((readl(&cmalwon->l3slowclkstctrl) & 0x2100) != 0x2100) ; } void setup_clocks_for_console(void) { unlock_pll_control_mmr(); /* UART0 */ writel(PRCM_MOD_EN, &cmalwon->uart0clkctrl); while (readl(&cmalwon->uart0clkctrl) != PRCM_MOD_EN) ; } /* * Configure the PLL/PRCM for necessary peripherals */ void prcm_init(void) { /* Enable the control module */ writel(PRCM_MOD_EN, &cmalwon->controlclkctrl); /* Configure PLLs */ mpu_pll_config(); l3_pll_config(); sata_pll_config(); /* Enable the required peripherals */ enable_per_clocks(); }