/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include struct mem_pll { u8 delay; u8 phase; u8 done; }; inline u8 is_dual_rank(u32 channel, const struct mt8173_sdram_params *sdram_params) { /* judge ranks from EMI_CONA[17] (cha) and EMI_CONA[16] (chb) */ return (sdram_params->emi_set.cona & (1 << (17 - channel))) ? 1 : 0; } static void mem_pll_pre_init(u32 channel) { write32(&ch[channel].ddrphy_regs->lpddr2_3, 0x1 << 29 | 0x1 << 25 | 0xf << 16 | 0xffff); write32(&ch[channel].ddrphy_regs->lpddr2_4, 0x1 << 29 | 0x1 << 25 | 0xf << 16 | 0xffff); /* adjust DQS/DQM phase to get best margin */ write32(&ch[channel].ddrphy_regs->selph12, 0x1 << 28 | 0xf << 20 | 0x1 << 12 | 0xf << 4); /* adjust DQ phase to get best margin */ write32(&ch[channel].ddrphy_regs->selph13, 0xffffffff << 0); write32(&ch[channel].ddrphy_regs->selph14, 0xffffffff << 0); /* fix OCV effect */ write32(&ch[channel].ddrphy_regs->selph15, 0x1 << 4 | 0xf << 0); /* pll register control by CPU and select internal pipe path */ write32(&ch[channel].ddrphy_regs->peri[2], 0x11 << 24 | 0x11 << 16 | 0xff << 8 | 0x11 << 0); write32(&ch[channel].ddrphy_regs->peri[3], 0x11 << 24 | 0x51 << 16 | 0x11 << 8 | 0x11 << 0); /* enable clock sync and spm control clock */ write32(&ch[channel].ddrphy_regs->mempll_divider, 0x9 << 24 | 0x1 << 15 | 0x2 << 4 | 0x1 << 1 | 0x1 << 0); /* pll2 enable from CPU control */ write32(&ch[channel].ddrphy_regs->mempll05_divider, 0x1 << 27); /* enable chip top memory clock */ setbits32(&ch[channel].ddrphy_regs->mempll_divider, 0x1 << 4); /* disable C/A and DQ M_CK clock gating */ clrbits32(&ch[channel].ddrphy_regs->ddrphy_cg_ctrl, 0x1 << 2 | 0x1 << 1); /* enable spm control clock */ clrbits32(&ch[channel].ddrphy_regs->mempll_divider, 0x1 << 15 | 0x1 << 0); /* enable dramc 2X mode */ setbits32(&ch[channel].ao_regs->ddr2ctl, 1 << 0); /* select internal clock path */ write32(&ch[channel].ddrphy_regs->peri[0], 0x21 << 24 | 0x27 << 16 | 0x1b << 8 | 0x3 << 0); write32(&ch[channel].ddrphy_regs->peri[1], 0x50 << 24 | 0x96 << 16 | 0x6 << 8 | 0x1e << 0); /* trigger to make memory clock correct phase */ setbits32(&ch[channel].ddrphy_regs->mempll_divider, 0x1 << 24 | 0x1 << 7); if (channel == CHANNEL_A) { /* select memory clock sync for channel A (internal source) */ clrbits32(&ch[channel].ddrphy_regs->mempll_divider, 0x1 << 3); } } static void mem_pll_init_set_params(u32 channel) { u32 pattern1, pattern2, pattern3; u32 mempll_ic_3_0, mempll_bp_3_0; u32 mempll_fbdiv_6_0, mempll_m4pdiv_1_0; u32 mempll_br_1_0, mempll_bc_1_0, mempll_ir_3_0; mempll_fbdiv_6_0 = 0x7 << 16; mempll_br_1_0 = 0x1 << 10; mempll_bc_1_0 = 0x0 << 8; mempll_ir_3_0 = 0xc << 28; mempll_ic_3_0 = 0x6 << 8; mempll_bp_3_0 = 0x1 << 12; mempll_m4pdiv_1_0 = 0x0 << 28; write32(&ch[channel].ddrphy_regs->mempll[14], 0x0); write32(&ch[channel].ddrphy_regs->mempll[3], 0x3 << 30 | 0x1 << 28); /* mempll 2 config */ pattern1 = mempll_ir_3_0 | mempll_fbdiv_6_0 | mempll_ic_3_0; pattern2 = mempll_m4pdiv_1_0; pattern3 = mempll_bp_3_0 | mempll_br_1_0 | mempll_bc_1_0; /* mempll2_autok_en = 1, mempll2_autok_load = 1 */ write32(&ch[channel].ddrphy_regs->mempll[5], 0x1 << 26 | 0x3 << 24 | 0x1 << 23 | pattern1); write32(&ch[channel].ddrphy_regs->mempll[6], 0x1 << 30 | 0x3 << 26 | 0x3 << 14 | pattern2); write32(&ch[channel].ddrphy_regs->mempll[7], 0x1 << 17 | 0x1 << 0 | pattern3); /* mempll 4 */ write32(&ch[channel].ddrphy_regs->mempll[11], 0x1 << 26 | 0x3 << 24 | 0x1 << 23 | pattern1); write32(&ch[channel].ddrphy_regs->mempll[12], 0x1 << 30 | 0x3 << 26 | 0x3 << 14 | pattern2); write32(&ch[channel].ddrphy_regs->mempll[13], 0x1 << 0 | pattern3); /* mempll 3 - enable signal tie together */ write32(&ch[channel].ddrphy_regs->mempll[8], 0x1 << 26 | 0x3 << 24 | 0x1 << 23 | pattern1); write32(&ch[channel].ddrphy_regs->mempll[9], 0x1 << 30 | 0x3 << 26 | 0x3 << 14 | pattern2); write32(&ch[channel].ddrphy_regs->mempll[10], 0x1 << 17 | 0x1 << 0 | pattern3); } static void mem_pll_init_phase_sync(u32 channel) { write32(&ch[channel].ddrphy_regs->mempll_divider, BIT(27) | BIT(24) | BIT(7) | BIT(5) | BIT(4) | BIT(0)); /* spm control clock enable */ clrsetbits32(&ch[channel].ddrphy_regs->mempll_divider, BIT(0), BIT(1)); clrsetbits32(&ch[channel].ddrphy_regs->mempll_divider, BIT(1), BIT(0)); } static void pll_phase_adjust(u32 channel, struct mem_pll *mempll, int reg_offs) { switch (mempll->phase) { case MEMPLL_INIT: /* initial phase: zero out RG_MEPLL(2,3,4)_(REF_DL,FB)_DL */ clrbits32(&ch[channel].ddrphy_regs->mempll[reg_offs], 0x1f << MEMPLL_REF_DL_SHIFT | 0x1f << MEMPLL_FB_DL_SHIFT); break; case MEMPLL_REF_LAG: /* REF lag FBK, delay FBK */ clrsetbits32(&ch[channel].ddrphy_regs->mempll[reg_offs], 0x1f << MEMPLL_REF_DL_SHIFT | 0x1f << MEMPLL_FB_DL_SHIFT, mempll->delay << MEMPLL_FB_DL_SHIFT); break; case MEMPLL_REF_LEAD: /* REF lead FBK, delay REF */ clrsetbits32(&ch[channel].ddrphy_regs->mempll[reg_offs], 0x1f << MEMPLL_REF_DL_SHIFT | 0x1f << MEMPLL_FB_DL_SHIFT, mempll->delay << MEMPLL_REF_DL_SHIFT); }; } static void pll_phase_check(u32 channel, struct mem_pll *mempll, int idx) { u32 value = read32(&ch[channel].ddrphy_regs->jmeter_pll_st[idx]); u16 one_count = (u16)((value >> 16) & 0xffff); u16 zero_count = (u16)(value & 0xffff); dramc_dbg("PLL %d, phase %d, one_count %d, zero_count %d\n", (idx + 2), mempll->phase, one_count, zero_count); switch (mempll->phase) { case MEMPLL_INIT: if ((one_count - zero_count) > JMETER_COUNT_N) { /* REF lag FBK */ mempll->phase = MEMPLL_REF_LAG; mempll->delay++; } else if ((zero_count - one_count) > JMETER_COUNT_N) { /* REF lead FBK */ mempll->phase = MEMPLL_REF_LEAD; mempll->delay++; } else { /* in-phase at initial */ mempll->done = 1; } break; case MEMPLL_REF_LAG: if (JMETER_COUNT_N >= (one_count - zero_count)) { mempll->done = 1; } else { mempll->delay++; } break; case MEMPLL_REF_LEAD: if (JMETER_COUNT_N >= (zero_count - one_count)) { mempll->done = 1; } else { mempll->delay++; } } } static void mem_pll_phase_cali(u32 channel) { u32 i; struct mem_pll mempll[3] = { {0, 0, 0}, {0, 0, 0}, {0, 0, 0}, }; dramc_dbg("[PLL_Phase_Calib] ===== PLL Phase Calibration: "); dramc_dbg("CHANNEL %d (0: CHA, 1: CHB) =====\n", channel); /* 1. set jitter meter count number to 1024 for mempll 2 3 4 */ for (i = 0; i < 3; i++) clrsetbits32(&ch[channel].ddrphy_regs->jmeter[i], JMETER_COUNTER_MASK, JMETER_COUNT << JMETER_COUNTER_SHIFT); while (1) { for (i = 0; i < 3; i++) { if (!mempll[i].done) { pll_phase_adjust(channel, &mempll[i], (i + 2) * 3); } } udelay(20); /* delay 20us for external loop pll stable */ /* 2. enable mempll 2 3 4 jitter meter */ for (i = 0; i < 3; i++) setbits32(&ch[channel].ddrphy_regs->jmeter[i], JMETER_EN_BIT); /* 3. wait for jitter meter complete */ udelay(JMETER_WAIT_DONE_US); /* 4. check jitter meter counter value for mempll 2 3 4 */ for (i = 0; i < 3; i++) { if (!mempll[i].done) { pll_phase_check(channel, &mempll[i], i); } } /* 5. disable mempll 2 3 4 jitter meter */ for (i = 0; i < 3; i++) clrbits32(&ch[channel].ddrphy_regs->jmeter[i], JMETER_EN_BIT); /* 6. all done early break */ if (mempll[0].done && mempll[1].done && mempll[2].done) break; /* 7. delay line overflow break */ for (i = 0; i < 3; i++) { if (mempll[i].delay >= 32) { die("MEMPLL calibration fail\n"); } } } dramc_dbg("pll done: "); dramc_dbg("%d, %d, %d\n", mempll[0].done, mempll[1].done, mempll[2].done); dramc_dbg("pll dl: %d, %d, %d\n", mempll[0].delay, mempll[1].delay, mempll[2].delay); } void mem_pll_init(const struct mt8173_sdram_params *sdram_params) { u32 channel; /* udelay waits for PLL to stabilize in this function */ printk(BIOS_DEBUG, "[PLL] mempll_init and cali\n"); /* mempll pre_init for two channels */ for (channel = 0; channel < CHANNEL_NUM; channel++) mem_pll_pre_init(channel); /* only set once in MPLL */ mt_mem_pll_config_pre(sdram_params); for (channel = 0; channel < CHANNEL_NUM; channel++) mem_pll_init_set_params(channel); udelay(1); /* wait after da_mpll_sdm_iso_en goes low */ /* only set once in MPLL */ mt_mem_pll_config_post(); udelay(100); for (channel = 0; channel < CHANNEL_NUM; channel++) { /* mempll_bias_en */ write32(&ch[channel].ddrphy_regs->mempll[3], 0xd << 28 | 0x1 << 6); udelay(2); /* mempll2_en -> mempll4_en -> mempll3_en */ setbits32(&ch[channel].ddrphy_regs->mempll[5], 1 << 0); setbits32(&ch[channel].ddrphy_regs->mempll[11], 1 << 0); setbits32(&ch[channel].ddrphy_regs->mempll[8], 1 << 0); udelay(100); /* mempll_bias_lpf_en */ setbits32(&ch[channel].ddrphy_regs->mempll[3], 1 << 7); udelay(30); /* select mempll4 band register */ setbits32(&ch[channel].ddrphy_regs->mempll[4], 1 << 26); clrbits32(&ch[channel].ddrphy_regs->mempll[4], 1 << 26); /* PLL ready */ /* disable mempll2_en -> mempll4_en -> mempll3_en */ clrbits32(&ch[channel].ddrphy_regs->mempll[5], 1 << 0); clrbits32(&ch[channel].ddrphy_regs->mempll[11], 1 << 0); clrbits32(&ch[channel].ddrphy_regs->mempll[8], 1 << 0); /* disable autok mempll2_en -> mempll4_en -> mempll3_en */ clrbits32(&ch[channel].ddrphy_regs->mempll[5], 1 << 23); clrbits32(&ch[channel].ddrphy_regs->mempll[11], 1 << 23); clrbits32(&ch[channel].ddrphy_regs->mempll[8], 1 << 23); udelay(1); /* mempll[2->4->3]_fb_mck_sel=1 (switch to outer loop) */ setbits32(&ch[channel].ddrphy_regs->mempll[6], 1 << 25); setbits32(&ch[channel].ddrphy_regs->mempll[12], 1 << 25); setbits32(&ch[channel].ddrphy_regs->mempll[9], 1 << 25); udelay(1); /* enable mempll2_en -> mempll4_en -> mempll3_en */ setbits32(&ch[channel].ddrphy_regs->mempll[5], 1 << 0); setbits32(&ch[channel].ddrphy_regs->mempll[11], 1 << 0); setbits32(&ch[channel].ddrphy_regs->mempll[8], 1 << 0); } /* mempll new power-on */ write32(&mtk_spm->poweron_config_set, 0x1 << 0 | SPM_PROJECT_CODE << 16); /* request mempll reset/pdn mode */ setbits32(&mtk_spm->power_on_val0, 0x1 << 27); udelay(2); /* unrequest mempll reset/pdn mode and wait settle */ clrbits32(&mtk_spm->power_on_val0, 0x1 << 27); udelay(31); /* PLL ready */ for (channel = 0; channel < CHANNEL_NUM; channel++) mem_pll_init_phase_sync(channel); udelay(1); /* mempll calibration for two channels */ for (channel = 0; channel < CHANNEL_NUM; channel++) mem_pll_phase_cali(channel); div2_phase_sync(); /* phase sync for channel B */ mt_mem_pll_mux(); } void dramc_pre_init(u32 channel, const struct mt8173_sdram_params *sdram_params) { /* txdly_cs, txdly_cs1 */ write32(&ch[channel].ao_regs->selph1, 0x0); /* txdly_dqsgate, txdly_dqsgate_p1 */ write32(&ch[channel].ao_regs->selph2, 0x3 << 20 | 0x2 << 12); /* txldy_ra* */ write32(&ch[channel].ao_regs->selph3, 0x0); /* txldy_ra* */ write32(&ch[channel].ao_regs->selph4, 0x0); /* setting of write latency (WL=8) */ write32(&ch[channel].ao_regs->selph7, 0x3333 << 16 | 0x3333); write32(&ch[channel].ao_regs->selph8, 0x3333 << 16 | 0x3333); write32(&ch[channel].ao_regs->selph9, 0x3333 << 16 | 0x3333); write32(&ch[channel].ao_regs->selph10, 0x5555 << 16 | 0xffff); write32(&ch[channel].ao_regs->selph11, 0x55 << 16 | 0xff); write32(&ch[channel].ao_regs->selph5, 0x1 << 26 | 0x2 << 22 | 0x1 << 20 | 0x5 << 16 | 0x5555); write32(&ch[channel].ao_regs->selph6_1, 0x4 << 8 | 0x3 << 4 | 0x2 << 0); write32(&ch[channel].ao_regs->ac_time_05t, sdram_params->ac_timing.actim05t); } static void mrs_write(int channel, int rank, u32 mrs_value, unsigned int dly) { write32(&ch[channel].ao_regs->mrs, rank << 28 | mrs_value); write32(&ch[channel].ao_regs->spcmd, 0x1); udelay(dly); write32(&ch[channel].ao_regs->spcmd, 0x0); } static void dramc_set_mrs_value(int channel, int rank, const struct mt8173_sdram_params *sdram_params) { /* MR63 -> Reset, Wait >=10us if not check DAI */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_63, 10); /* MR10 -> ZQ Init, tZQINIT>=1us */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_10, 1); /* MR3 driving strength set to max */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_3, 1); /* MR1 */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_1, 1); /* MR2 */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_2, 1); /* MR11 ODT disable */ mrs_write(channel, rank, sdram_params->mrs_set.mrs_11, 1); } void dramc_init(u32 channel, const struct mt8173_sdram_params *sdram_params) { u32 bit, dual_rank_set; const struct mt8173_calib_params *calib_params; dual_rank_set = is_dual_rank(channel, sdram_params); calib_params = &sdram_params->calib_params; write32(&ch[channel].ddrphy_regs->peri[2], 0x1 << 12 | 0x1 << 4); write32(&ch[channel].ddrphy_regs->peri[3], 0x0); write32(&ch[channel].ao_regs->test2_4, sdram_params->ac_timing.test2_4); write32(&ch[channel].ao_regs->clk1delay, 0x1 << 23 | 0x1 << 22 | 0x1 << 21); /* rank config */ assert((sdram_params->ac_timing.rkcfg & 0x1) == dual_rank_set); write32(&ch[channel].ao_regs->rkcfg, sdram_params->ac_timing.rkcfg); /* pimux */ write32(&ch[channel].ao_regs->mckdly, 0x1 << 30 | 0x1 << 20 | 0x1 << 4); write32(&ch[channel].ddrphy_regs->mckdly, 0x1 << 8); write32(&ch[channel].ao_regs->padctl4, 0x1 << 0); /* tCKEH/tCKEL extend 1T */ write32(&ch[channel].ao_regs->dummy, 0x1 << 31 | 0x3 << 10 | 0x1 << 4); /* driving control */ write32(&ch[channel].ao_regs->iodrv6, DEFAULT_DRIVING | DRIVING_DS2_0 << 20 | DRIVING_DS2_0 << 4); write32(&ch[channel].ddrphy_regs->drvctl1, DEFAULT_DRIVING | DRIVING_DS2_0 << 20); write32(&ch[channel].ao_regs->drvctl1, DEFAULT_DRIVING | DRIVING_DS2_0 << 4); /* enable dqs signal output */ write32(&ch[channel].ddrphy_regs->ioctl, 0x0); /* rank 0 dqs gating delay */ write32(&ch[channel].ao_regs->dqsien[0], 0x40 << 24 | 0x40 << 16 | 0x40 << 8 | 0x40 << 0); write32(&ch[channel].ao_regs->dqsctl1, 0x1 << 28 | 0x5 << 24); write32(&ch[channel].ao_regs->dqsctl2, 0x5 << 0); write32(&ch[channel].ao_regs->phyctl1, 0x1 << 25); write32(&ch[channel].ao_regs->gddr3ctl1, 0x1 << 24); write32(&ch[channel].ddrphy_regs->gddr3ctl1, 0x1 << 28); write32(&ch[channel].ao_regs->arbctl0, 0x80 << 0); /* enable clock pad 0 */ write32(&ch[channel].ao_regs->clkctl, 0x1 << 28); udelay(1); write32(&ch[channel].ao_regs->conf1, sdram_params->ac_timing.conf1); /* bit 17,18 would bypass some dummy path */ write32(&ch[channel].ddrphy_regs->dqsgctl, 0x1 << 31 | 0x1 << 30 | 0x1 << 17 | 0x1 << 18 | 0x1 << 4 | 0x1 << 0); write32(&ch[channel].ao_regs->dqscal0, 0x0); write32(&ch[channel].ddrphy_regs->dqscal0, 0x0); write32(&ch[channel].ao_regs->actim0, sdram_params->ac_timing.actim); write32(&ch[channel].ao_regs->misctl0, sdram_params->ac_timing.misctl0); write32(&ch[channel].ddrphy_regs->misctl0, sdram_params->ac_timing.misctl0); write32(&ch[channel].ao_regs->perfctl0, 0x1 << 20); write32(&ch[channel].ao_regs->ddr2ctl, sdram_params->ac_timing.ddr2ctl); write32(&ch[channel].ddrphy_regs->ddr2ctl, sdram_params->ac_timing.ddr2ctl); write32(&ch[channel].ao_regs->misc, 0xb << 8 | 0x1 << 7 | 0x1 << 6 | 0x1 << 5); write32(&ch[channel].ao_regs->dllconf, 0xf << 28 | 0x1 << 24); write32(&ch[channel].ao_regs->actim1, sdram_params->ac_timing.actim1); write32(&ch[channel].ddrphy_regs->dqsisel, 0x0); /* disable ODT before ZQ calibration */ write32(&ch[channel].ao_regs->wodt, 0x1 << 0); write32(&ch[channel].ao_regs->padctl4, 0x1 << 2 | 0x1 << 0); udelay(200); /* tINIT3 > 200us */ write32(&ch[channel].ao_regs->gddr3ctl1, 0x1 << 24 | 0x1 << 20); write32(&ch[channel].ddrphy_regs->gddr3ctl1, 0x1 << 28); /* set mode register value */ dramc_set_mrs_value(channel, 0, sdram_params); if (dual_rank_set) dramc_set_mrs_value(channel, 1, sdram_params); write32(&ch[channel].ao_regs->gddr3ctl1, sdram_params->ac_timing.gddr3ctl1); write32(&ch[channel].ddrphy_regs->gddr3ctl1, sdram_params->ac_timing.gddr3ctl1); write32(&ch[channel].ao_regs->dramc_pd_ctrl, sdram_params->ac_timing.pd_ctrl); write32(&ch[channel].ao_regs->padctl4, 0x1 << 0); write32(&ch[channel].ao_regs->perfctl0, 0x1 << 20 | 0x1 << 0); write32(&ch[channel].ao_regs->zqcs, 0xa << 8 | 0x56 << 0); write32(&ch[channel].ddrphy_regs->padctl1, 0x0); write32(&ch[channel].ao_regs->test2_3, sdram_params->ac_timing.test2_3); write32(&ch[channel].ao_regs->conf2, sdram_params->ac_timing.conf2); write32(&ch[channel].ddrphy_regs->padctl2, 0x0); /* DISABLE_DRVREF */ write32(&ch[channel].ao_regs->ocdk, 0x0); write32(&ch[channel].ddrphy_regs->ocdk, 0x0); write32(&ch[channel].ao_regs->r1deldly, 0x12 << 24 | 0x12 << 16 | 0x12 << 8 | 0x12 << 0); write32(&ch[channel].ao_regs->padctl7, 0x0); /* CLKTDN, DS0TDN, DS1TDN, DS2TDN, DS3TDN */ setbits32(&ch[channel].ddrphy_regs->tdsel[2], 0x1 << 31 | 0x1 << 29 | 0x1 << 27 | 0x1 << 25 | 0x1 << 1); /* DISABLE_PERBANK_REFRESH */ clrbits32(&ch[channel].ao_regs->rkcfg, 0x1 << 7); /* clear R_DMREFTHD to reduce MR4 wait refresh queue time */ clrbits32(&ch[channel].ao_regs->conf2, 0x7 << 24); /* duty default value */ write32(&ch[channel].ddrphy_regs->phyclkduty, 0x1 << 28 | 0x1 << 16); if (!dual_rank_set) { /* single rank, CKE1 always off */ setbits32(&ch[channel].ao_regs->gddr3ctl1, 0x1 << 21); } /* default dqs rx perbit input delay */ write32(&ch[channel].ao_regs->r0deldly, calib_params->rx_dqs_dly[channel]); write32(&ch[channel].ao_regs->r1deldly, calib_params->rx_dqs_dly[channel]); for (bit = 0; bit < DQS_BIT_NUMBER; bit++) write32(&ch[channel].ao_regs->dqidly[bit], calib_params->rx_dq_dly[channel][bit]); } void div2_phase_sync(void) { clrbits32(&ch[CHANNEL_B].ddrphy_regs->mempll_divider, 1 << MEMCLKENB_SHIFT); udelay(1); setbits32(&ch[CHANNEL_B].ddrphy_regs->mempll_divider, 1 << MEMCLKENB_SHIFT); } void dramc_phy_reset(u32 channel) { /* reset phy */ setbits32(&ch[channel].ddrphy_regs->phyctl1, 1 << PHYCTL1_PHYRST_SHIFT); /* read data counter reset */ setbits32(&ch[channel].ao_regs->gddr3ctl1, 1 << GDDR3CTL1_RDATRST_SHIFT); udelay(1); /* delay 1ns */ clrbits32(&ch[channel].ao_regs->gddr3ctl1, 1 << GDDR3CTL1_RDATRST_SHIFT); clrbits32(&ch[channel].ddrphy_regs->phyctl1, 1 << PHYCTL1_PHYRST_SHIFT); } void dramc_runtime_config(u32 channel, const struct mt8173_sdram_params *sdram_params) { setbits32(&ch[channel].ddrphy_regs->dqsgctl, BIT(17)|BIT(18)); /* enable hw gating */ setbits32(&ch[channel].ao_regs->dqscal0, 1 << DQSCAL0_STBCALEN_SHIFT); /* if frequency >1600, tCKE should >7 clk */ setbits32(&ch[channel].ao_regs->dummy, 0x1 << 4); if (sdram_params->dram_freq * 2 < 1600 * MHz) die("set tCKE error in runtime config"); /* DDRPHY C/A and DQ M_CK clock gating enable */ setbits32(&ch[channel].ddrphy_regs->ddrphy_cg_ctrl, 0x1 << 2 | 0x1 << 1); setbits32(&ch[channel].ao_regs->perfctl0, BIT(19) | BIT(14) | BIT(11) | BIT(10) | BIT(9) | BIT(8) | BIT(4) | BIT(0)); /* ZQCS_ENABLE */ if (sdram_params->emi_set.cona & 0x1) { /* dual channel, clear ZQCSCNT */ clrbits32(&ch[channel].ao_regs->spcmd, 0xff << 16); /* set ZQCSMASK for different channels */ if (channel == CHANNEL_A) { clrbits32(&ch[channel].ao_regs->perfctl0, 0x1 << 24); } else { setbits32(&ch[channel].ao_regs->perfctl0, 0x1 << 24); } /* enable ZQCSDUAL */ setbits32(&ch[channel].ao_regs->perfctl0, 0x1 << 25); } else { /* single channel, set ZQCSCNT */ setbits32(&ch[channel].ao_regs->spcmd, 0x8 << 16); } } void transfer_to_spm_control(void) { u32 msk; msk = BIT(7) | BIT(11) | BIT(15); clrbits32(&mtk_apmixed->ap_pll_con3, msk); msk = BIT(0) | BIT(4) | BIT(8); clrbits32(&ch[CHANNEL_A].ddrphy_regs->peri[3], msk); msk = BIT(0) | BIT(8); clrbits32(&ch[CHANNEL_B].ddrphy_regs->peri[3], msk); msk = BIT(0) | BIT(9) | BIT(10) | BIT(11) | BIT(16) | BIT(24); clrbits32(&ch[CHANNEL_A].ddrphy_regs->peri[2], msk); clrbits32(&ch[CHANNEL_B].ddrphy_regs->peri[2], msk); } void transfer_to_reg_control(void) { u32 val; val = BIT(7) | BIT(11) | BIT(15); setbits32(&mtk_apmixed->ap_pll_con3, val); val = BIT(0) | BIT(4) | BIT(8); setbits32(&ch[CHANNEL_A].ddrphy_regs->peri[3], val); val = BIT(0) | BIT(8); write32(&ch[CHANNEL_B].ddrphy_regs->peri[3], val); val = BIT(0) | BIT(9) | BIT(10) | BIT(11) | BIT(16) | BIT(24); setbits32(&ch[CHANNEL_A].ddrphy_regs->peri[2], val); setbits32(&ch[CHANNEL_B].ddrphy_regs->peri[2], val); } u32 dramc_engine2(u32 channel, enum dram_tw_op wr, u32 test2_1, u32 test2_2, u8 testaudpat, u8 log2loopcount) { u32 value; if (log2loopcount > 15) die("Invalid loopcount of engine2!"); /* Disable Test Agent1, Test Agent2 write/read */ clrbits32(&ch[channel].ao_regs->conf2, CONF2_TEST1_EN | CONF2_TEST2R_EN | CONF2_TEST2W_EN); /* 1. set pattern, base address, offset address */ write32(&ch[channel].nao_regs->test2_1, test2_1); write32(&ch[channel].nao_regs->test2_2, test2_2); /* 2. select test pattern */ /* TESTXTALKPAT | TESTAUDPAT * ISI 0 | 0 * AUD 0 | 1 * XTALK 1 | 0 * UNKNOWN 1 | 1 */ switch (testaudpat) { case XTALK: /* TESTAUDPAT = 0 */ clrbits32(&ch[channel].ao_regs->test2_3, TEST2_3_TESTAUDPAT_EN); /* TESTXTALKPAT = 1, select xtalk pattern * TESTAUDMODE = 0, read only * TESTAUDBITINV = 0, no bit inversion */ clrsetbits32(&ch[channel].ao_regs->test2_4, TEST2_4_TESTAUDBITINV_EN | TEST2_4_TESTAUDMODE_EN, TEST2_4_TESTXTALKPAT_EN); break; case AUDIO: /* TESTAUDPAT = 1 */ setbits32(&ch[channel].ao_regs->test2_3, TEST2_3_TESTAUDPAT_EN); /* TESTXTALKPAT = 0 * TESTAUDINIT = 0x11 * TESTAUDINC = 0x0d * TESTAUDBITINV = 1 * TESTAUDMODE = 1 */ clrsetbits32(&ch[channel].ao_regs->test2_4, TEST2_4_TESTXTALKPAT_EN | TEST2_4_TESTAUDINIT_MASK | TEST2_4_TESTAUDINC_MASK, TEST2_4_TESTAUDMODE_EN | TEST2_4_TESTAUDBITINV_EN | 0x11 << TEST2_4_TESTAUDINIT_SHIFT | 0xd << TEST2_4_TESTAUDINC_SHIFT); break; case ISI: /* TESTAUDPAT = 0 */ clrbits32(&ch[channel].ao_regs->test2_3, TEST2_3_TESTAUDPAT_EN); /* TESTXTALKPAT = 0 */ clrbits32(&ch[channel].ao_regs->test2_4, TEST2_4_TESTXTALKPAT_EN); } /* 3. set loop number */ clrsetbits32(&ch[channel].ao_regs->test2_3, TEST2_3_TESTCNT_MASK, log2loopcount << TEST2_3_TESTCNT_SHIFT); /* 4. enable read/write test */ if (wr == TE_OP_READ_CHECK) { if ((testaudpat == 1) || (testaudpat == 2)) { /* if audio pattern, enable read only */ /* (disable write after read), */ /* AUDMODE=0x48[15]=0 */ clrbits32(&ch[channel].ao_regs->test2_4, TEST2_4_TESTAUDMODE_EN); } /* enable read, 0x008[30:30] */ setbits32(&ch[channel].ao_regs->conf2, CONF2_TEST2R_EN); } else if (wr == TE_OP_WRITE_READ_CHECK) { /* enable write, 0x008[31:31] */ setbits32(&ch[channel].ao_regs->conf2, CONF2_TEST2W_EN); /* check "read data compare ready" bit */ do { value = read32(&ch[channel].nao_regs->testrpt); } while ((value & (1 << TESTRPT_DM_CMP_CPT_SHIFT)) == 0); /* Disable Test Agent2 write and enable Test Agent2 read */ clrbits32(&ch[channel].ao_regs->conf2, CONF2_TEST2W_EN); setbits32(&ch[channel].ao_regs->conf2, CONF2_TEST2R_EN); } /* 5 check "read data compare ready" bit */ do { value = read32(&ch[channel].nao_regs->testrpt); } while ((value & (1 << TESTRPT_DM_CMP_CPT_SHIFT)) == 0); /* delay 10ns after ready check from DE suggestion (1us here) */ udelay(1); /* read CMP_ERR result */ value = read32(&ch[channel].nao_regs->cmp_err); /* 6 disable read */ clrbits32(&ch[channel].ao_regs->conf2, CONF2_TEST2R_EN); /* return CMP_ERR result, pass: 0, failure: otherwise */ return value; }