/* * Copyright (C) 2012 Alexey Galakhov * * Based on code from u-boot found somewhere on the web * that seems to originate from Samsung * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of * the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #define S5P_DMC_CONCONTROL 0x00 #define S5P_DMC_MEMCONTROL 0x04 #define S5P_DMC_MEMCONFIG0 0x08 #define S5P_DMC_MEMCONFIG1 0x0C #define S5P_DMC_DIRECTCMD 0x10 #define S5P_DMC_PRECHCONFIG 0x14 #define S5P_DMC_PHYCONTROL0 0x18 #define S5P_DMC_PHYCONTROL1 0x1C #define S5P_DMC_PWRDNCONFIG 0x28 #define S5P_DMC_TIMINGAREF 0x30 #define S5P_DMC_TIMINGROW 0x34 #define S5P_DMC_TIMINGDATA 0x38 #define S5P_DMC_TIMINGPOWER 0x3C #define S5P_DMC_PHYSTATUS 0x40 #define S5P_DMC_MRSTATUS 0x54 /* DRAM commands */ #define CMD(x) ((x) << 24) #define BANK(x) ((x) << 16) #define CHIP(x) ((x) << 20) #define ADDR(x) (x) /** * MR definition: * 1 11 * 2 1098 7654 3210 * | | ^^^- burst length, 010=4, 011=8 * | | ^- burst type 0=sequnential, 1=interleaved * | ^^^-- CAS latency * | ^----- test, 0=normal, 1=test * |^---- DLL reset, 1=yes * ^^^----- WR, 1=2, 2=3 etc. * ^------- PD, 0=fast exit, 1=low power * * EMR1 definition: * 1 11 * 2 1098 7654 3210 * | ^- DLL, 0=enable * | ^-- output strength, 0=full, 1=reduced * |^.. .^--- Rtt, 00=off, 01=75, 10=150, 11=50 Ohm * | ^^ ^-- Posted CAS# AL, 0-6 * ^^ ^------ OCD: 000=OCD exit, 111=enable defaults * ^------ DQS#, 0=enable, 1=disable * ^------- RDQS enable, 0=no, 1=yes * ^-------- outputs, 0=enabled, 1=disabled * * EMR2 definition: * bit 7 * 1 1 * 2 1098 7654 3210 * ^-- SRT, 0=1x (0-85 deg.C), 1=2x (>85 deg.C) * all other bits = 0 * * EMR3 definition: all bits 0 */ #define MRS CMD(0x0) #define PALL CMD(0x1) #define PRE CMD(0x2) #define DPD CMD(0x3) #define REFS CMD(0x4) #define REFA CMD(0x5) #define CKEL CMD(0x6) #define NOP CMD(0x7) #define REFSX CMD(0x8) #define MRR CMD(0x9) #define EMRS1 (MRS | BANK(1)) #define EMRS2 (MRS | BANK(2)) #define EMRS3 (MRS | BANK(3)) /* Burst is (1 << S5P_DRAM_BURST), i.e. S5P_DRAM_BURST=2 for burst 4 */ #ifndef S5P_DRAM_BURST /* (LP)DDR2 supports burst 4 only, make it default */ # define S5P_DRAM_BURST 2 #endif /** * Initialization sequences for different kinds of DRAM */ #define dcmd(x) writel((x) | CHIP(chip), base + S5P_DMC_DIRECTCMD) static void __bare_init s5p_dram_init_seq_lpddr(phys_addr_t base, unsigned chip) { const uint32_t emr = 0x400; /* DQS disable */ const uint32_t mr = (((S5P_DRAM_WR) - 1) << 9) | ((S5P_DRAM_CAS) << 4) | (S5P_DRAM_BURST); /* TODO this sequence is untested */ dcmd(PALL); dcmd(REFA); dcmd(REFA); dcmd(MRS | ADDR(mr)); dcmd(EMRS1 | ADDR(emr)); } static void __bare_init s5p_dram_init_seq_lpddr2(phys_addr_t base, unsigned chip) { const uint32_t mr = (((S5P_DRAM_WR) - 1) << 9) | ((S5P_DRAM_CAS) << 4) | (S5P_DRAM_BURST); /* TODO this sequence is untested */ dcmd(NOP); dcmd(MRS | ADDR(mr)); do { dcmd(MRR); } while (readl(base + S5P_DMC_MRSTATUS) & 0x01); /* poll DAI */ } static void __bare_init s5p_dram_init_seq_ddr2(phys_addr_t base, unsigned chip) { const uint32_t emr = 0x400; /* DQS disable */ const uint32_t mr = (((S5P_DRAM_WR) - 1) << 9) | ((S5P_DRAM_CAS) << 4) | (S5P_DRAM_BURST); dcmd(NOP); /* FIXME wait here? JEDEC recommends but nobody does */ dcmd(PALL); dcmd(EMRS2); dcmd(EMRS3); dcmd(EMRS1 | ADDR(emr)); /* DQS disable */ dcmd(MRS | ADDR(mr | 0x100)); /* DLL reset */ dcmd(PALL); dcmd(REFA); dcmd(REFA); dcmd(MRS | ADDR(mr)); /* DLL no reset */ dcmd(EMRS1 | ADDR(emr | 0x380)); /* OCD defaults */ dcmd(EMRS1 | ADDR(emr)); /* OCD exit */ } #undef dcmd static inline void __bare_init s5p_dram_start_dll(phys_addr_t base, uint32_t phycon1) { uint32_t pc0 = 0x00101000; /* the only legal initial value */ uint32_t lv; /* Init DLL */ writel(pc0, base + S5P_DMC_PHYCONTROL0); writel(phycon1, base + S5P_DMC_PHYCONTROL1); /* DLL on */ pc0 |= 0x2; writel(pc0, base + S5P_DMC_PHYCONTROL0); /* DLL start */ pc0 |= 0x1; writel(pc0, base + S5P_DMC_PHYCONTROL0); /* Find lock val */ do { lv = readl(base + S5P_DMC_PHYSTATUS); } while ((lv & 0x7) != 0x7); lv >>= 6; lv &= 0xff; /* ctrl_lock_value[9:2] - coarse */ pc0 |= (lv << 24); /* ctrl_force */ writel(pc0, base + S5P_DMC_PHYCONTROL0); /* force value locking */ } static inline void __bare_init s5p_dram_setup(phys_addr_t base, uint32_t mc0, uint32_t mc1, int bus16, uint32_t mcon) { mcon |= (S5P_DRAM_BURST) << 20; /* 16 or 32-bit bus ? */ mcon |= bus16 ? 0x1000 : 0x2000; if (mc1) mcon |= 0x10000; /* two chips */ writel(mcon, base + S5P_DMC_MEMCONTROL); /* Set up memory layout */ writel(mc0, base + S5P_DMC_MEMCONFIG0); if (mc1) writel(mc1, base + S5P_DMC_MEMCONFIG1); /* Open page precharge policy - reasonable defaults */ writel(0xFF000000, base + S5P_DMC_PRECHCONFIG); /* Set up timings */ writel(DMC_TIMING_AREF, base + S5P_DMC_TIMINGAREF); writel(DMC_TIMING_ROW, base + S5P_DMC_TIMINGROW); writel(DMC_TIMING_DATA, base + S5P_DMC_TIMINGDATA); writel(DMC_TIMING_PWR, base + S5P_DMC_TIMINGPOWER); } static inline void __bare_init s5p_dram_start(phys_addr_t base) { /* Reasonable defaults and auto-refresh on */ writel(0x0FFF1070, base + S5P_DMC_CONCONTROL); /* Reasonable defaults */ writel(0xFFFF00FF, base + S5P_DMC_PWRDNCONFIG); } /* * Initialize LPDDR memory bank * TODO: this function is untested, see also init_seq function */ void __bare_init s5p_init_dram_bank_lpddr(phys_addr_t base, uint32_t mc0, uint32_t mc1, int bus16) { /* refcount 8, 90 deg. shift */ s5p_dram_start_dll(base, 0x00000085); /* LPDDR type */ s5p_dram_setup(base, mc0, mc1, bus16, 0x100); /* Start-Up Commands */ s5p_dram_init_seq_lpddr(base, 0); if (mc1) s5p_dram_init_seq_lpddr(base, 1); s5p_dram_start(base); } /* * Initialize LPDDR2 memory bank * TODO: this function is untested, see also init_seq function */ void __bare_init s5p_init_dram_bank_lpddr2(phys_addr_t base, uint32_t mc0, uint32_t mc1, int bus16) { /* refcount 8, 90 deg. shift */ s5p_dram_start_dll(base, 0x00000085); /* LPDDR2 type */ s5p_dram_setup(base, mc0, mc1, bus16, 0x200); /* Start-Up Commands */ s5p_dram_init_seq_lpddr2(base, 0); if (mc1) s5p_dram_init_seq_lpddr2(base, 1); s5p_dram_start(base); } /* * Initialize DDR2 memory bank */ void __bare_init s5p_init_dram_bank_ddr2(phys_addr_t base, uint32_t mc0, uint32_t mc1, int bus16) { /* refcount 8, 180 deg. shift */ s5p_dram_start_dll(base, 0x00000086); /* DDR2 type */ s5p_dram_setup(base, mc0, mc1, bus16, 0x400); /* Start-Up Commands */ s5p_dram_init_seq_ddr2(base, 0); if (mc1) s5p_dram_init_seq_ddr2(base, 1); s5p_dram_start(base); } #define BANK_ENABLED(base) (readl((base) + S5P_DMC_PHYCONTROL0) & 1) #define NUM_EXTRA_CHIPS(base) ((readl((base) + S5P_DMC_MEMCONTROL) >> 16) & 0xF) #define BANK_START(x) ((x) & 0xFF000000) #define BANK_END(x) (BANK_START(x) | ~(((x) & 0x00FF0000) << 8)) #define BANK_LEN(x) (BANK_END(x) - BANK_START(x) + 1) static inline void sortswap(uint32_t *x, uint32_t *y) { if (*y < *x) { *x ^= *y; *y ^= *x; *x ^= *y; } } uint32_t s5p_get_memory_size(void) { int i; uint32_t len; uint32_t mc[4] = { 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF }; /* Read MEMCONFIG registers */ if (BANK_ENABLED(S5P_DMC0_BASE)) { mc[0] = readl(S5P_DMC0_BASE + S5P_DMC_MEMCONFIG0); if (NUM_EXTRA_CHIPS(S5P_DMC0_BASE) > 0) mc[1] = readl(S5P_DMC0_BASE + S5P_DMC_MEMCONFIG1); } if (BANK_ENABLED(S5P_DMC1_BASE)) { mc[2] = readl(S5P_DMC1_BASE + S5P_DMC_MEMCONFIG0); if (NUM_EXTRA_CHIPS(S5P_DMC1_BASE) > 0) mc[3] = readl(S5P_DMC1_BASE + S5P_DMC_MEMCONFIG1); } /* Sort using a sorting network */ sortswap(mc + 0, mc + 2); sortswap(mc + 1, mc + 3); sortswap(mc + 0, mc + 1); sortswap(mc + 2, mc + 3); sortswap(mc + 1, mc + 2); /* Is at least one chip enabled? */ if (mc[0] == 0xFFFFFFFF) return 0; /* Determine maximum continuous region at start */ len = BANK_LEN(mc[0]); for (i = 1; i < 4; ++i) { if (BANK_START(mc[i]) == BANK_END(mc[i - 1]) + 1) len += BANK_LEN(mc[i]); else break; } return len; }