// SPDX-License-Identifier: GPL-2.0+ /* * (C) Copyright 2013-2016, Freescale Semiconductor, Inc. */ #include #include #include #include #include #include #include #include #include #include #include #include u32 get_cpu_rev(void) { struct mscm_ir *mscmir = (struct mscm_ir *)MSCM_BASE_ADDR; u32 cpu = readl(&mscmir->cpxtype); return cpu; } DECLARE_GLOBAL_DATA_PTR; static uintptr_t get_pllfreq(u32 pll, u32 refclk_freq, u32 plldv, u32 pllfd, u32 selected_output) { u32 vco = 0, plldv_prediv = 0, plldv_mfd = 0, pllfd_mfn = 0; u32 plldv_rfdphi_div = 0, fout = 0; u32 dfs_portn = 0, dfs_mfn = 0, dfs_mfi = 0; if (selected_output > DFS_MAXNUMBER) { return -1; } plldv_prediv = (plldv & PLLDIG_PLLDV_PREDIV_MASK) >> PLLDIG_PLLDV_PREDIV_OFFSET; plldv_mfd = (plldv & PLLDIG_PLLDV_MFD_MASK); pllfd_mfn = (pllfd & PLLDIG_PLLFD_MFN_MASK); plldv_prediv = plldv_prediv == 0 ? 1 : plldv_prediv; /* The formula for VCO is from TR manual, rev. D */ vco = refclk_freq / plldv_prediv * (plldv_mfd + pllfd_mfn / 20481); if (selected_output != 0) { /* Determine the RFDPHI for PHI1 */ plldv_rfdphi_div = (plldv & PLLDIG_PLLDV_RFDPHI1_MASK) >> PLLDIG_PLLDV_RFDPHI1_OFFSET; plldv_rfdphi_div = plldv_rfdphi_div == 0 ? 1 : plldv_rfdphi_div; if (pll == ARM_PLL || pll == ENET_PLL || pll == DDR_PLL) { dfs_portn = readl(DFS_DVPORTn(pll, selected_output - 1)); dfs_mfi = (dfs_portn & DFS_DVPORTn_MFI_MASK) >> DFS_DVPORTn_MFI_OFFSET; dfs_mfn = (dfs_portn & DFS_DVPORTn_MFI_MASK) >> DFS_DVPORTn_MFI_OFFSET; fout = vco / (dfs_mfi + (dfs_mfn / 256)); } else { fout = vco / plldv_rfdphi_div; } } else { /* Determine the RFDPHI for PHI0 */ plldv_rfdphi_div = (plldv & PLLDIG_PLLDV_RFDPHI_MASK) >> PLLDIG_PLLDV_RFDPHI_OFFSET; fout = vco / plldv_rfdphi_div; } return fout; } /* Implemented for ARMPLL, PERIPH_PLL, ENET_PLL, DDR_PLL, VIDEO_LL */ static uintptr_t decode_pll(enum pll_type pll, u32 refclk_freq, u32 selected_output) { u32 plldv, pllfd; plldv = readl(PLLDIG_PLLDV(pll)); pllfd = readl(PLLDIG_PLLFD(pll)); return get_pllfreq(pll, refclk_freq, plldv, pllfd, selected_output); } static u32 get_mcu_main_clk(void) { u32 coreclk_div; u32 sysclk_sel; u32 freq = 0; sysclk_sel = readl(CGM_SC_SS(MC_CGM1_BASE_ADDR)) & MC_CGM_SC_SEL_MASK; sysclk_sel >>= MC_CGM_SC_SEL_OFFSET; coreclk_div = readl(CGM_SC_DCn(MC_CGM1_BASE_ADDR, 0)) & MC_CGM_SC_DCn_PREDIV_MASK; coreclk_div >>= MC_CGM_SC_DCn_PREDIV_OFFSET; coreclk_div += 1; switch (sysclk_sel) { case MC_CGM_SC_SEL_FIRC: freq = FIRC_CLK_FREQ; break; case MC_CGM_SC_SEL_XOSC: freq = XOSC_CLK_FREQ; break; case MC_CGM_SC_SEL_ARMPLL: /* ARMPLL has as source XOSC and CORE_CLK has as input PHI0 */ freq = decode_pll(ARM_PLL, XOSC_CLK_FREQ, 0); break; case MC_CGM_SC_SEL_CLKDISABLE: printf("Sysclk is disabled\n"); break; default: printf("unsupported system clock select\n"); } return freq / coreclk_div; } static u32 get_sys_clk(u32 number) { u32 sysclk_div, sysclk_div_number; u32 sysclk_sel; u32 freq = 0; switch (number) { case 3: sysclk_div_number = 0; break; case 6: sysclk_div_number = 1; break; default: printf("unsupported system clock \n"); return -1; } sysclk_sel = readl(CGM_SC_SS(MC_CGM0_BASE_ADDR)) & MC_CGM_SC_SEL_MASK; sysclk_sel >>= MC_CGM_SC_SEL_OFFSET; sysclk_div = readl(CGM_SC_DCn(MC_CGM1_BASE_ADDR, sysclk_div_number)) & MC_CGM_SC_DCn_PREDIV_MASK; sysclk_div >>= MC_CGM_SC_DCn_PREDIV_OFFSET; sysclk_div += 1; switch (sysclk_sel) { case MC_CGM_SC_SEL_FIRC: freq = FIRC_CLK_FREQ; break; case MC_CGM_SC_SEL_XOSC: freq = XOSC_CLK_FREQ; break; case MC_CGM_SC_SEL_ARMPLL: /* ARMPLL has as source XOSC and SYSn_CLK has as input DFS1 */ freq = decode_pll(ARM_PLL, XOSC_CLK_FREQ, 1); break; case MC_CGM_SC_SEL_CLKDISABLE: printf("Sysclk is disabled\n"); break; default: printf("unsupported system clock select\n"); } return freq / sysclk_div; } static u32 get_peripherals_clk(void) { u32 aux5clk_div; u32 freq = 0; aux5clk_div = readl(CGM_ACn_DCm(MC_CGM0_BASE_ADDR, 5, 0)) & MC_CGM_ACn_DCm_PREDIV_MASK; aux5clk_div >>= MC_CGM_ACn_DCm_PREDIV_OFFSET; aux5clk_div += 1; freq = decode_pll(PERIPH_PLL, XOSC_CLK_FREQ, 0); return freq / aux5clk_div; } static u32 get_uart_clk(void) { u32 auxclk3_div, auxclk3_sel, freq = 0; auxclk3_sel = readl(CGM_ACn_SS(MC_CGM0_BASE_ADDR, 3)) & MC_CGM_ACn_SEL_MASK; auxclk3_sel >>= MC_CGM_ACn_SEL_OFFSET; auxclk3_div = readl(CGM_ACn_DCm(MC_CGM0_BASE_ADDR, 3, 0)) & MC_CGM_ACn_DCm_PREDIV_MASK; auxclk3_div >>= MC_CGM_ACn_DCm_PREDIV_OFFSET; auxclk3_div += 1; switch (auxclk3_sel) { case MC_CGM_ACn_SEL_FIRC: freq = FIRC_CLK_FREQ; break; case MC_CGM_ACn_SEL_XOSC: freq = XOSC_CLK_FREQ; break; case MC_CGM_ACn_SEL_PERPLLDIVX: freq = get_peripherals_clk() / 3; break; case MC_CGM_ACn_SEL_SYSCLK: freq = get_sys_clk(6); break; default: printf("unsupported system clock select\n"); } return freq / auxclk3_div; } static u32 get_fec_clk(void) { u32 aux2clk_div; u32 freq = 0; aux2clk_div = readl(CGM_ACn_DCm(MC_CGM0_BASE_ADDR, 2, 0)) & MC_CGM_ACn_DCm_PREDIV_MASK; aux2clk_div >>= MC_CGM_ACn_DCm_PREDIV_OFFSET; aux2clk_div += 1; freq = decode_pll(ENET_PLL, XOSC_CLK_FREQ, 0); return freq / aux2clk_div; } static u32 get_usdhc_clk(void) { u32 aux15clk_div; u32 freq = 0; aux15clk_div = readl(CGM_ACn_DCm(MC_CGM0_BASE_ADDR, 15, 0)) & MC_CGM_ACn_DCm_PREDIV_MASK; aux15clk_div >>= MC_CGM_ACn_DCm_PREDIV_OFFSET; aux15clk_div += 1; freq = decode_pll(ENET_PLL, XOSC_CLK_FREQ, 4); return freq / aux15clk_div; } static u32 get_i2c_clk(void) { return get_peripherals_clk(); } /* return clocks in Hz */ unsigned int mxc_get_clock(enum mxc_clock clk) { switch (clk) { case MXC_ARM_CLK: return get_mcu_main_clk(); case MXC_PERIPHERALS_CLK: return get_peripherals_clk(); case MXC_UART_CLK: return get_uart_clk(); case MXC_FEC_CLK: return get_fec_clk(); case MXC_I2C_CLK: return get_i2c_clk(); case MXC_USDHC_CLK: return get_usdhc_clk(); default: break; } printf("Error: Unsupported function to read the frequency! \ Please define it correctly!"); return -1; } /* Not yet implemented - int soc_clk_dump(); */ #if defined(CONFIG_DISPLAY_CPUINFO) static char *get_reset_cause(void) { u32 cause = readl(MC_RGM_BASE_ADDR + 0x300); switch (cause) { case F_SWT4: return "WDOG"; case F_JTAG: return "JTAG"; case F_FCCU_SOFT: return "FCCU soft reaction"; case F_FCCU_HARD: return "FCCU hard reaction"; case F_SOFT_FUNC: return "Software Functional reset"; case F_ST_DONE: return "Self Test done reset"; case F_EXT_RST: return "External reset"; default: return "unknown reset"; } } #define SRC_SCR_SW_RST (1<<12) void reset_cpu(ulong addr) { printf("Feature not supported.\n"); }; int print_cpuinfo(void) { printf("CPU: Freescale Treerunner S32V234 at %d MHz\n", mxc_get_clock(MXC_ARM_CLK) / 1000000); printf("Reset cause: %s\n", get_reset_cause()); return 0; } #endif int cpu_eth_init(bd_t * bis) { int rc = -ENODEV; #if defined(CONFIG_FEC_MXC) rc = fecmxc_initialize(bis); #endif return rc; } int get_clocks(void) { #ifdef CONFIG_FSL_ESDHC_IMX gd->arch.sdhc_clk = mxc_get_clock(MXC_USDHC_CLK); #endif return 0; }