/************************************************************************ * * Copyright (c) 2013-2015 Intel Corporation. * * This program and the accompanying materials * are licensed and made available under the terms and conditions of the BSD License * which accompanies this distribution. The full text of the license may be found at * http://opensource.org/licenses/bsd-license.php * * THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, * WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. * ***************************************************************************/ #include "mrc.h" #include "memory_options.h" #include "meminit_utils.h" #include "hte.h" #include "io.h" void select_hte( MRCParams_t *mrc_params); static uint8_t first_run = 0; const uint8_t vref_codes[64] = { // lowest to highest 0x3F, 0x3E, 0x3D, 0x3C, 0x3B, 0x3A, 0x39, 0x38, 0x37, 0x36, 0x35, 0x34, 0x33, 0x32, 0x31, 0x30, // 00 - 15 0x2F, 0x2E, 0x2D, 0x2C, 0x2B, 0x2A, 0x29, 0x28, 0x27, 0x26, 0x25, 0x24, 0x23, 0x22, 0x21, 0x20, // 16 - 31 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0A, 0x0B, 0x0C, 0x0D, 0x0E, 0x0F, // 32 - 47 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1A, 0x1B, 0x1C, 0x1D, 0x1E, 0x1F // 48 - 63 }; #ifdef EMU // Track current post code for debugging purpose uint32_t PostCode; #endif // set_rcvn: // // This function will program the RCVEN delays. // (currently doesn't comprehend rank) void set_rcvn( uint8_t channel, uint8_t rank, uint8_t byte_lane, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); DPF(D_TRN, "Rcvn ch%d rnk%d ln%d : pi=%03X\n", channel, rank, byte_lane, pi_count); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[11:08] (0x0-0xF) // BL1 -> B01PTRCTL0[23:20] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = (byte_lane & BIT0) ? (BIT23 | BIT22 | BIT21 | BIT20) : (BIT11 | BIT10 | BIT9 | BIT8); tempD = (byte_lane & BIT0) ? ((pi_count / HALF_CLK) << 20) : ((pi_count / HALF_CLK) << 8); isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[29:24] (0x00-0x3F) // BL1 -> B1DLLPICODER0[29:24] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); msk = (BIT29 | BIT28 | BIT27 | BIT26 | BIT25 | BIT24); tempD = pi_count << 24; isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // BL0/1 -> B01DBCTL1[08/11] (+1 select) // BL0/1 -> B01DBCTL1[02/05] (enable) reg = B01DBCTL1 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= (byte_lane & BIT0) ? (BIT5) : (BIT2); if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= (byte_lane & BIT0) ? (BIT11) : (BIT8); if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { training_message(channel, rank, byte_lane); post_code(0xEE, 0xE0); } LEAVEFN(); return; } // get_rcvn: // // This function will return the current RCVEN delay on the given channel, rank, byte_lane as an absolute PI count. // (currently doesn't comprehend rank) uint32_t get_rcvn( uint8_t channel, uint8_t rank, uint8_t byte_lane) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[11:08] (0x0-0xF) // BL1 -> B01PTRCTL0[23:20] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= (byte_lane & BIT0) ? (20) : (8); tempD &= 0xF; // Adjust PI_COUNT pi_count = tempD * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[29:24] (0x00-0x3F) // BL1 -> B1DLLPICODER0[29:24] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); tempD = isbR32m(DDRPHY, reg); tempD >>= 24; tempD &= 0x3F; // Adjust PI_COUNT pi_count += tempD; LEAVEFN(); return pi_count; } // set_rdqs: // // This function will program the RDQS delays based on an absolute amount of PIs. // (currently doesn't comprehend rank) void set_rdqs( uint8_t channel, uint8_t rank, uint8_t byte_lane, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); DPF(D_TRN, "Rdqs ch%d rnk%d ln%d : pi=%03X\n", channel, rank, byte_lane, pi_count); // PI (1/128 MCLK) // BL0 -> B0RXDQSPICODE[06:00] (0x00-0x47) // BL1 -> B1RXDQSPICODE[06:00] (0x00-0x47) reg = (byte_lane & BIT0) ? (B1RXDQSPICODE) : (B0RXDQSPICODE); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); msk = (BIT6 | BIT5 | BIT4 | BIT3 | BIT2 | BIT1 | BIT0); tempD = pi_count << 0; isbM32m(DDRPHY, reg, tempD, msk); // error check (shouldn't go above 0x3F) if (pi_count > 0x47) { training_message(channel, rank, byte_lane); post_code(0xEE, 0xE1); } LEAVEFN(); return; } // get_rdqs: // // This function will return the current RDQS delay on the given channel, rank, byte_lane as an absolute PI count. // (currently doesn't comprehend rank) uint32_t get_rdqs( uint8_t channel, uint8_t rank, uint8_t byte_lane) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // PI (1/128 MCLK) // BL0 -> B0RXDQSPICODE[06:00] (0x00-0x47) // BL1 -> B1RXDQSPICODE[06:00] (0x00-0x47) reg = (byte_lane & BIT0) ? (B1RXDQSPICODE) : (B0RXDQSPICODE); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); tempD = isbR32m(DDRPHY, reg); // Adjust PI_COUNT pi_count = tempD & 0x7F; LEAVEFN(); return pi_count; } // set_wdqs: // // This function will program the WDQS delays based on an absolute amount of PIs. // (currently doesn't comprehend rank) void set_wdqs( uint8_t channel, uint8_t rank, uint8_t byte_lane, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); DPF(D_TRN, "Wdqs ch%d rnk%d ln%d : pi=%03X\n", channel, rank, byte_lane, pi_count); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[07:04] (0x0-0xF) // BL1 -> B01PTRCTL0[19:16] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = (byte_lane & BIT0) ? (BIT19 | BIT18 | BIT17 | BIT16) : (BIT7 | BIT6 | BIT5 | BIT4); tempD = pi_count / HALF_CLK; tempD <<= (byte_lane & BIT0) ? (16) : (4); isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[21:16] (0x00-0x3F) // BL1 -> B1DLLPICODER0[21:16] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); msk = (BIT21 | BIT20 | BIT19 | BIT18 | BIT17 | BIT16); tempD = pi_count << 16; isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // BL0/1 -> B01DBCTL1[07/10] (+1 select) // BL0/1 -> B01DBCTL1[01/04] (enable) reg = B01DBCTL1 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= (byte_lane & BIT0) ? (BIT4) : (BIT1); if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= (byte_lane & BIT0) ? (BIT10) : (BIT7); if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { training_message(channel, rank, byte_lane); post_code(0xEE, 0xE2); } LEAVEFN(); return; } // get_wdqs: // // This function will return the amount of WDQS delay on the given channel, rank, byte_lane as an absolute PI count. // (currently doesn't comprehend rank) uint32_t get_wdqs( uint8_t channel, uint8_t rank, uint8_t byte_lane) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[07:04] (0x0-0xF) // BL1 -> B01PTRCTL0[19:16] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= (byte_lane & BIT0) ? (16) : (4); tempD &= 0xF; // Adjust PI_COUNT pi_count = (tempD * HALF_CLK); // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[21:16] (0x00-0x3F) // BL1 -> B1DLLPICODER0[21:16] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); tempD = isbR32m(DDRPHY, reg); tempD >>= 16; tempD &= 0x3F; // Adjust PI_COUNT pi_count += tempD; LEAVEFN(); return pi_count; } // set_wdq: // // This function will program the WDQ delays based on an absolute number of PIs. // (currently doesn't comprehend rank) void set_wdq( uint8_t channel, uint8_t rank, uint8_t byte_lane, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); DPF(D_TRN, "Wdq ch%d rnk%d ln%d : pi=%03X\n", channel, rank, byte_lane, pi_count); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[03:00] (0x0-0xF) // BL1 -> B01PTRCTL0[15:12] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = (byte_lane & BIT0) ? (BIT15 | BIT14 | BIT13 | BIT12) : (BIT3 | BIT2 | BIT1 | BIT0); tempD = pi_count / HALF_CLK; tempD <<= (byte_lane & BIT0) ? (12) : (0); isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[13:08] (0x00-0x3F) // BL1 -> B1DLLPICODER0[13:08] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); msk = (BIT13 | BIT12 | BIT11 | BIT10 | BIT9 | BIT8); tempD = pi_count << 8; isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // BL0/1 -> B01DBCTL1[06/09] (+1 select) // BL0/1 -> B01DBCTL1[00/03] (enable) reg = B01DBCTL1 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= (byte_lane & BIT0) ? (BIT3) : (BIT0); if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= (byte_lane & BIT0) ? (BIT9) : (BIT6); if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { training_message(channel, rank, byte_lane); post_code(0xEE, 0xE3); } LEAVEFN(); return; } // get_wdq: // // This function will return the amount of WDQ delay on the given channel, rank, byte_lane as an absolute PI count. // (currently doesn't comprehend rank) uint32_t get_wdq( uint8_t channel, uint8_t rank, uint8_t byte_lane) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // BL0 -> B01PTRCTL0[03:00] (0x0-0xF) // BL1 -> B01PTRCTL0[15:12] (0x0-0xF) reg = B01PTRCTL0 + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= (byte_lane & BIT0) ? (12) : (0); tempD &= 0xF; // Adjust PI_COUNT pi_count = (tempD * HALF_CLK); // PI (1/64 MCLK, 1 PIs) // BL0 -> B0DLLPICODER0[13:08] (0x00-0x3F) // BL1 -> B1DLLPICODER0[13:08] (0x00-0x3F) reg = (byte_lane & BIT0) ? (B1DLLPICODER0) : (B0DLLPICODER0); reg += (((byte_lane >> 1) * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET)); tempD = isbR32m(DDRPHY, reg); tempD >>= 8; tempD &= 0x3F; // Adjust PI_COUNT pi_count += tempD; LEAVEFN(); return pi_count; } // set_wcmd: // // This function will program the WCMD delays based on an absolute number of PIs. void set_wcmd( uint8_t channel, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CMDPTRREG[11:08] (0x0-0xF) reg = CMDPTRREG + (channel * DDRIOCCC_CH_OFFSET); msk = (BIT11 | BIT10 | BIT9 | BIT8); tempD = pi_count / HALF_CLK; tempD <<= 8; isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // CMDDLLPICODER0[29:24] -> CMDSLICE R3 (unused) // CMDDLLPICODER0[21:16] -> CMDSLICE L3 (unused) // CMDDLLPICODER0[13:08] -> CMDSLICE R2 (unused) // CMDDLLPICODER0[05:00] -> CMDSLICE L2 (unused) // CMDDLLPICODER1[29:24] -> CMDSLICE R1 (unused) // CMDDLLPICODER1[21:16] -> CMDSLICE L1 (0x00-0x3F) // CMDDLLPICODER1[13:08] -> CMDSLICE R0 (unused) // CMDDLLPICODER1[05:00] -> CMDSLICE L0 (unused) reg = CMDDLLPICODER1 + (channel * DDRIOCCC_CH_OFFSET); msk = (BIT29 | BIT28 | BIT27 | BIT26 | BIT25 | BIT24) | (BIT21 | BIT20 | BIT19 | BIT18 | BIT17 | BIT16) | (BIT13 | BIT12 | BIT11 | BIT10 | BIT9 | BIT8) | (BIT5 | BIT4 | BIT3 | BIT2 | BIT1 | BIT0); tempD = (pi_count << 24) | (pi_count << 16) | (pi_count << 8) | (pi_count << 0); isbM32m(DDRPHY, reg, tempD, msk); reg = CMDDLLPICODER0 + (channel * DDRIOCCC_CH_OFFSET); // PO isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // CMDCFGREG0[17] (+1 select) // CMDCFGREG0[16] (enable) reg = CMDCFGREG0 + (channel * DDRIOCCC_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= BIT16; if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= BIT17; if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { post_code(0xEE, 0xE4); } LEAVEFN(); return; } // get_wcmd: // // This function will return the amount of WCMD delay on the given channel as an absolute PI count. uint32_t get_wcmd( uint8_t channel) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CMDPTRREG[11:08] (0x0-0xF) reg = CMDPTRREG + (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= 8; tempD &= 0xF; // Adjust PI_COUNT pi_count = tempD * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // CMDDLLPICODER0[29:24] -> CMDSLICE R3 (unused) // CMDDLLPICODER0[21:16] -> CMDSLICE L3 (unused) // CMDDLLPICODER0[13:08] -> CMDSLICE R2 (unused) // CMDDLLPICODER0[05:00] -> CMDSLICE L2 (unused) // CMDDLLPICODER1[29:24] -> CMDSLICE R1 (unused) // CMDDLLPICODER1[21:16] -> CMDSLICE L1 (0x00-0x3F) // CMDDLLPICODER1[13:08] -> CMDSLICE R0 (unused) // CMDDLLPICODER1[05:00] -> CMDSLICE L0 (unused) reg = CMDDLLPICODER1 + (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= 16; tempD &= 0x3F; // Adjust PI_COUNT pi_count += tempD; LEAVEFN(); return pi_count; } // set_wclk: // // This function will program the WCLK delays based on an absolute number of PIs. void set_wclk( uint8_t channel, uint8_t rank, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CCPTRREG[15:12] -> CLK1 (0x0-0xF) // CCPTRREG[11:08] -> CLK0 (0x0-0xF) reg = CCPTRREG + (channel * DDRIOCCC_CH_OFFSET); msk = (BIT15 | BIT14 | BIT13 | BIT12) | (BIT11 | BIT10 | BIT9 | BIT8); tempD = ((pi_count / HALF_CLK) << 12) | ((pi_count / HALF_CLK) << 8); isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // ECCB1DLLPICODER0[13:08] -> CLK0 (0x00-0x3F) // ECCB1DLLPICODER0[21:16] -> CLK1 (0x00-0x3F) reg = (rank) ? (ECCB1DLLPICODER0) : (ECCB1DLLPICODER0); reg += (channel * DDRIOCCC_CH_OFFSET); msk = (BIT21 | BIT20 | BIT19 | BIT18 | BIT17 | BIT16) | (BIT13 | BIT12 | BIT11 | BIT10 | BIT9 | BIT8); tempD = (pi_count << 16) | (pi_count << 8); isbM32m(DDRPHY, reg, tempD, msk); reg = (rank) ? (ECCB1DLLPICODER1) : (ECCB1DLLPICODER1); reg += (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); reg = (rank) ? (ECCB1DLLPICODER2) : (ECCB1DLLPICODER2); reg += (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); reg = (rank) ? (ECCB1DLLPICODER3) : (ECCB1DLLPICODER3); reg += (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // CCCFGREG1[11:08] (+1 select) // CCCFGREG1[03:00] (enable) reg = CCCFGREG1 + (channel * DDRIOCCC_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= (BIT3 | BIT2 | BIT1 | BIT0); // only ??? matters if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= (BIT11 | BIT10 | BIT9 | BIT8); // only ??? matters if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { post_code(0xEE, 0xE5); } LEAVEFN(); return; } // get_wclk: // // This function will return the amout of WCLK delay on the given channel, rank as an absolute PI count. uint32_t get_wclk( uint8_t channel, uint8_t rank) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CCPTRREG[15:12] -> CLK1 (0x0-0xF) // CCPTRREG[11:08] -> CLK0 (0x0-0xF) reg = CCPTRREG + (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= (rank) ? (12) : (8); tempD &= 0xF; // Adjust PI_COUNT pi_count = tempD * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // ECCB1DLLPICODER0[13:08] -> CLK0 (0x00-0x3F) // ECCB1DLLPICODER0[21:16] -> CLK1 (0x00-0x3F) reg = (rank) ? (ECCB1DLLPICODER0) : (ECCB1DLLPICODER0); reg += (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= (rank) ? (16) : (8); tempD &= 0x3F; pi_count += tempD; LEAVEFN(); return pi_count; } // set_wctl: // // This function will program the WCTL delays based on an absolute number of PIs. // (currently doesn't comprehend rank) void set_wctl( uint8_t channel, uint8_t rank, uint32_t pi_count) { uint32_t reg; uint32_t msk; uint32_t tempD; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CCPTRREG[31:28] (0x0-0xF) // CCPTRREG[27:24] (0x0-0xF) reg = CCPTRREG + (channel * DDRIOCCC_CH_OFFSET); msk = (BIT31 | BIT30 | BIT29 | BIT28) | (BIT27 | BIT26 | BIT25 | BIT24); tempD = ((pi_count / HALF_CLK) << 28) | ((pi_count / HALF_CLK) << 24); isbM32m(DDRPHY, reg, tempD, msk); // Adjust PI_COUNT pi_count -= ((pi_count / HALF_CLK) & 0xF) * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // ECCB1DLLPICODER?[29:24] (0x00-0x3F) // ECCB1DLLPICODER?[29:24] (0x00-0x3F) reg = ECCB1DLLPICODER0 + (channel * DDRIOCCC_CH_OFFSET); msk = (BIT29 | BIT28 | BIT27 | BIT26 | BIT25 | BIT24); tempD = (pi_count << 24); isbM32m(DDRPHY, reg, tempD, msk); reg = ECCB1DLLPICODER1 + (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); reg = ECCB1DLLPICODER2 + (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); reg = ECCB1DLLPICODER3 + (channel * DDRIOCCC_CH_OFFSET); isbM32m(DDRPHY, reg, tempD, msk); // DEADBAND // CCCFGREG1[13:12] (+1 select) // CCCFGREG1[05:04] (enable) reg = CCCFGREG1 + (channel * DDRIOCCC_CH_OFFSET); msk = 0x00; tempD = 0x00; // enable msk |= (BIT5 | BIT4); // only ??? matters if ((pi_count < EARLY_DB) || (pi_count > LATE_DB)) { tempD |= msk; } // select msk |= (BIT13 | BIT12); // only ??? matters if (pi_count < EARLY_DB) { tempD |= msk; } isbM32m(DDRPHY, reg, tempD, msk); // error check if (pi_count > 0x3F) { post_code(0xEE, 0xE6); } LEAVEFN(); return; } // get_wctl: // // This function will return the amount of WCTL delay on the given channel, rank as an absolute PI count. // (currently doesn't comprehend rank) uint32_t get_wctl( uint8_t channel, uint8_t rank) { uint32_t reg; uint32_t tempD; uint32_t pi_count; ENTERFN(); // RDPTR (1/2 MCLK, 64 PIs) // CCPTRREG[31:28] (0x0-0xF) // CCPTRREG[27:24] (0x0-0xF) reg = CCPTRREG + (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= 24; tempD &= 0xF; // Adjust PI_COUNT pi_count = tempD * HALF_CLK; // PI (1/64 MCLK, 1 PIs) // ECCB1DLLPICODER?[29:24] (0x00-0x3F) // ECCB1DLLPICODER?[29:24] (0x00-0x3F) reg = ECCB1DLLPICODER0 + (channel * DDRIOCCC_CH_OFFSET); tempD = isbR32m(DDRPHY, reg); tempD >>= 24; tempD &= 0x3F; // Adjust PI_COUNT pi_count += tempD; LEAVEFN(); return pi_count; } // set_vref: // // This function will program the internal Vref setting in a given byte lane in a given channel. void set_vref( uint8_t channel, uint8_t byte_lane, uint32_t setting) { uint32_t reg = (byte_lane & 0x1) ? (B1VREFCTL) : (B0VREFCTL); ENTERFN(); DPF(D_TRN, "Vref ch%d ln%d : val=%03X\n", channel, byte_lane, setting); isbM32m(DDRPHY, (reg + (channel * DDRIODQ_CH_OFFSET) + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET)), (vref_codes[setting] << 2), (BIT7 | BIT6 | BIT5 | BIT4 | BIT3 | BIT2)); //isbM32m(DDRPHY, (reg + (channel * DDRIODQ_CH_OFFSET) + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET)), (setting<<2), (BIT7|BIT6|BIT5|BIT4|BIT3|BIT2)); // need to wait ~300ns for Vref to settle (check that this is necessary) delay_n(300); // ??? may need to clear pointers ??? LEAVEFN(); return; } // get_vref: // // This function will return the internal Vref setting for the given channel, byte_lane; uint32_t get_vref( uint8_t channel, uint8_t byte_lane) { uint8_t j; uint32_t ret_val = sizeof(vref_codes) / 2; uint32_t reg = (byte_lane & 0x1) ? (B1VREFCTL) : (B0VREFCTL); uint32_t tempD; ENTERFN(); tempD = isbR32m(DDRPHY, (reg + (channel * DDRIODQ_CH_OFFSET) + ((byte_lane >> 1) * DDRIODQ_BL_OFFSET))); tempD >>= 2; tempD &= 0x3F; for (j = 0; j < sizeof(vref_codes); j++) { if (vref_codes[j] == tempD) { ret_val = j; break; } } LEAVEFN(); return ret_val; } // clear_pointers: // // This function will be used to clear the pointers in a given byte lane in a given channel. void clear_pointers( void) { uint8_t channel_i; uint8_t bl_i; ENTERFN(); for (channel_i = 0; channel_i < NUM_CHANNELS; channel_i++) { for (bl_i = 0; bl_i < NUM_BYTE_LANES; bl_i++) { isbM32m(DDRPHY, (B01PTRCTL1 + (channel_i * DDRIODQ_CH_OFFSET) + ((bl_i >> 1) * DDRIODQ_BL_OFFSET)), ~(BIT8), (BIT8)); //delay_m(1); // DEBUG isbM32m(DDRPHY, (B01PTRCTL1 + (channel_i * DDRIODQ_CH_OFFSET) + ((bl_i >> 1) * DDRIODQ_BL_OFFSET)), (BIT8), (BIT8)); } } LEAVEFN(); return; } // void enable_cache: void enable_cache( void) { // Cache control not used in Quark MRC return; } // void disable_cache: void disable_cache( void) { // Cache control not used in Quark MRC return; } // Send DRAM command, data should be formated // using DCMD_Xxxx macro or emrsXCommand structure. static void dram_init_command( uint32_t data) { Wr32(DCMD, 0, data); } // find_rising_edge: // // This function will find the rising edge transition on RCVN or WDQS. void find_rising_edge( MRCParams_t *mrc_params, uint32_t delay[], uint8_t channel, uint8_t rank, bool rcvn) { #define SAMPLE_CNT 3 // number of sample points #define SAMPLE_DLY 26 // number of PIs to increment per sample #define FORWARD true // indicates to increase delays when looking for edge #define BACKWARD false // indicates to decrease delays when looking for edge bool all_edges_found; // determines stop condition bool direction[NUM_BYTE_LANES]; // direction indicator uint8_t sample_i; // sample counter uint8_t bl_i; // byte lane counter uint8_t bl_divisor = (mrc_params->channel_width == x16) ? 2 : 1; // byte lane divisor uint32_t sample_result[SAMPLE_CNT]; // results of "sample_dqs()" uint32_t tempD; // temporary DWORD uint32_t transition_pattern; ENTERFN(); // select hte and request initial configuration select_hte(mrc_params); first_run = 1; // Take 3 sample points (T1,T2,T3) to obtain a transition pattern. for (sample_i = 0; sample_i < SAMPLE_CNT; sample_i++) { // program the desired delays for sample for (bl_i = 0; bl_i < (NUM_BYTE_LANES / bl_divisor); bl_i++) { // increase sample delay by 26 PI (0.2 CLK) if (rcvn) { set_rcvn(channel, rank, bl_i, delay[bl_i] + (sample_i * SAMPLE_DLY)); } else { set_wdqs(channel, rank, bl_i, delay[bl_i] + (sample_i * SAMPLE_DLY)); } } // bl_i loop // take samples (Tsample_i) sample_result[sample_i] = sample_dqs(mrc_params, channel, rank, rcvn); DPF(D_TRN, "Find rising edge %s ch%d rnk%d: #%d dly=%d dqs=%02X\n", (rcvn ? "RCVN" : "WDQS"), channel, rank, sample_i, sample_i * SAMPLE_DLY, sample_result[sample_i]); } // sample_i loop // This pattern will help determine where we landed and ultimately how to place RCVEN/WDQS. for (bl_i = 0; bl_i < (NUM_BYTE_LANES / bl_divisor); bl_i++) { // build "transition_pattern" (MSB is 1st sample) transition_pattern = 0x00; for (sample_i = 0; sample_i < SAMPLE_CNT; sample_i++) { transition_pattern |= ((sample_result[sample_i] & (1 << bl_i)) >> bl_i) << (SAMPLE_CNT - 1 - sample_i); } // sample_i loop DPF(D_TRN, "=== transition pattern %d\n", transition_pattern); // set up to look for rising edge based on "transition_pattern" switch (transition_pattern) { case 0x00: // sampled 0->0->0 // move forward from T3 looking for 0->1 delay[bl_i] += 2 * SAMPLE_DLY; direction[bl_i] = FORWARD; break; case 0x01: // sampled 0->0->1 case 0x05: // sampled 1->0->1 (bad duty cycle) *HSD#237503* // move forward from T2 looking for 0->1 delay[bl_i] += 1 * SAMPLE_DLY; direction[bl_i] = FORWARD; break; // HSD#237503 // case 0x02: // sampled 0->1->0 (bad duty cycle) // training_message(channel, rank, bl_i); // post_code(0xEE, 0xE8); // break; case 0x02: // sampled 0->1->0 (bad duty cycle) *HSD#237503* case 0x03: // sampled 0->1->1 // move forward from T1 looking for 0->1 delay[bl_i] += 0 * SAMPLE_DLY; direction[bl_i] = FORWARD; break; case 0x04: // sampled 1->0->0 (assumes BL8, HSD#234975) // move forward from T3 looking for 0->1 delay[bl_i] += 2 * SAMPLE_DLY; direction[bl_i] = FORWARD; break; // HSD#237503 // case 0x05: // sampled 1->0->1 (bad duty cycle) // training_message(channel, rank, bl_i); // post_code(0xEE, 0xE9); // break; case 0x06: // sampled 1->1->0 case 0x07: // sampled 1->1->1 // move backward from T1 looking for 1->0 delay[bl_i] += 0 * SAMPLE_DLY; direction[bl_i] = BACKWARD; break; default: post_code(0xEE, 0xEE); break; } // transition_pattern switch // program delays if (rcvn) { set_rcvn(channel, rank, bl_i, delay[bl_i]); } else { set_wdqs(channel, rank, bl_i, delay[bl_i]); } } // bl_i loop // Based on the observed transition pattern on the byte lane, // begin looking for a rising edge with single PI granularity. do { all_edges_found = true; // assume all byte lanes passed tempD = sample_dqs(mrc_params, channel, rank, rcvn); // take a sample // check all each byte lane for proper edge for (bl_i = 0; bl_i < (NUM_BYTE_LANES / bl_divisor); bl_i++) { if (tempD & (1 << bl_i)) { // sampled "1" if (direction[bl_i] == BACKWARD) { // keep looking for edge on this byte lane all_edges_found = false; delay[bl_i] -= 1; if (rcvn) { set_rcvn(channel, rank, bl_i, delay[bl_i]); } else { set_wdqs(channel, rank, bl_i, delay[bl_i]); } } } else { // sampled "0" if (direction[bl_i] == FORWARD) { // keep looking for edge on this byte lane all_edges_found = false; delay[bl_i] += 1; if (rcvn) { set_rcvn(channel, rank, bl_i, delay[bl_i]); } else { set_wdqs(channel, rank, bl_i, delay[bl_i]); } } } } // bl_i loop } while (!all_edges_found); // restore DDR idle state dram_init_command(DCMD_PREA(rank)); DPF(D_TRN, "Delay %03X %03X %03X %03X\n", delay[0], delay[1], delay[2], delay[3]); LEAVEFN(); return; } // sample_dqs: // // This function will sample the DQTRAINSTS registers in the given channel/rank SAMPLE_SIZE times looking for a valid '0' or '1'. // It will return an encoded DWORD in which each bit corresponds to the sampled value on the byte lane. uint32_t sample_dqs( MRCParams_t *mrc_params, uint8_t channel, uint8_t rank, bool rcvn) { uint8_t j; // just a counter uint8_t bl_i; // which BL in the module (always 2 per module) uint8_t bl_grp; // which BL module uint8_t bl_divisor = (mrc_params->channel_width == x16) ? 2 : 1; // byte lane divisor uint32_t msk[2]; // BLx in module uint32_t sampled_val[SAMPLE_SIZE]; // DQTRAINSTS register contents for each sample uint32_t num_0s; // tracks the number of '0' samples uint32_t num_1s; // tracks the number of '1' samples uint32_t ret_val = 0x00; // assume all '0' samples uint32_t address = get_addr(mrc_params, channel, rank); // initialise "msk[]" msk[0] = (rcvn) ? (BIT1) : (BIT9); // BL0 msk[1] = (rcvn) ? (BIT0) : (BIT8); // BL1 // cycle through each byte lane group for (bl_grp = 0; bl_grp < (NUM_BYTE_LANES / bl_divisor) / 2; bl_grp++) { // take SAMPLE_SIZE samples for (j = 0; j < SAMPLE_SIZE; j++) { HteMemOp(address, first_run, rcvn?0:1); first_run = 0; // record the contents of the proper DQTRAINSTS register sampled_val[j] = isbR32m(DDRPHY, (DQTRAINSTS + (bl_grp * DDRIODQ_BL_OFFSET) + (channel * DDRIODQ_CH_OFFSET))); } // look for a majority value ( (SAMPLE_SIZE/2)+1 ) on the byte lane // and set that value in the corresponding "ret_val" bit for (bl_i = 0; bl_i < 2; bl_i++) { num_0s = 0x00; // reset '0' tracker for byte lane num_1s = 0x00; // reset '1' tracker for byte lane for (j = 0; j < SAMPLE_SIZE; j++) { if (sampled_val[j] & msk[bl_i]) { num_1s++; } else { num_0s++; } } if (num_1s > num_0s) { ret_val |= (1 << (bl_i + (bl_grp * 2))); } } } // "ret_val.0" contains the status of BL0 // "ret_val.1" contains the status of BL1 // "ret_val.2" contains the status of BL2 // etc. return ret_val; } // get_addr: // // This function will return a 32 bit address in the desired channel and rank. uint32_t get_addr( MRCParams_t *mrc_params, uint8_t channel, uint8_t rank) { uint32_t offset = 0x02000000; // 32MB // Begin product specific code if (channel > 0) { DPF(D_ERROR, "ILLEGAL CHANNEL\n"); DEAD_LOOP(); } if (rank > 1) { DPF(D_ERROR, "ILLEGAL RANK\n"); DEAD_LOOP(); } // use 256MB lowest density as per DRP == 0x0003 offset += rank * (256 * 1024 * 1024); return offset; } // byte_lane_mask: // // This function will return a 32 bit mask that will be used to check for byte lane failures. uint32_t byte_lane_mask( MRCParams_t *mrc_params) { uint32_t j; uint32_t ret_val = 0x00; // set "ret_val" based on NUM_BYTE_LANES such that you will check only BL0 in "result" // (each bit in "result" represents a byte lane) for (j = 0; j < MAX_BYTE_LANES; j += NUM_BYTE_LANES) { ret_val |= (1 << ((j / NUM_BYTE_LANES) * NUM_BYTE_LANES)); } // HSD#235037 // need to adjust the mask for 16-bit mode if (mrc_params->channel_width == x16) { ret_val |= (ret_val << 2); } return ret_val; } // read_tsc: // // This function will do some assembly to return TSC register contents as a uint64_t. uint64_t read_tsc( void) { volatile uint64_t tsc; // EDX:EAX #if defined (SIM) || defined (GCC) volatile uint32_t tscH; // EDX volatile uint32_t tscL;// EAX asm("rdtsc":"=a"(tscL),"=d"(tscH)); tsc = tscH; tsc = (tsc<<32)|tscL; #else tsc = __rdtsc(); #endif return tsc; } // get_tsc_freq: // // This function returns the TSC frequency in MHz uint32_t get_tsc_freq( void) { static uint32_t freq[] = { 533, 400, 200, 100 }; uint32_t fuse; #if 0 fuse = (isbR32m(FUSE, 0) >> 12) & (BIT1|BIT0); #else // todo!!! Fixed 533MHz for emulation or debugging fuse = 0; #endif return freq[fuse]; } #ifndef SIM // delay_n: // // This is a simple delay function. // It takes "nanoseconds" as a parameter. void delay_n( uint32_t nanoseconds) { // 1000 MHz clock has 1ns period --> no conversion required uint64_t final_tsc = read_tsc(); final_tsc += ((get_tsc_freq() * (nanoseconds)) / 1000); while (read_tsc() < final_tsc) ; return; } #endif // delay_u: // // This is a simple delay function. // It takes "microseconds as a parameter. void delay_u( uint32_t microseconds) { // 64 bit math is not an option, just use loops while (microseconds--) { delay_n(1000); } return; } // delay_m: // // This is a simple delay function. // It takes "milliseconds" as a parameter. void delay_m( uint32_t milliseconds) { // 64 bit math is not an option, just use loops while (milliseconds--) { delay_u(1000); } return; } // delay_s: // // This is a simple delay function. // It takes "seconds" as a parameter. void delay_s( uint32_t seconds) { // 64 bit math is not an option, just use loops while (seconds--) { delay_m(1000); } return; } // post_code: // // This function will output the POST CODE to the four 7-Segment LED displays. void post_code( uint8_t major, uint8_t minor) { #ifdef EMU // Update global variable for execution tracking in debug env PostCode = ((major << 8) | minor); #endif // send message to UART DPF(D_INFO, "POST: 0x%01X%02X\n", major, minor); // error check: if (major == 0xEE) { // todo!!! Consider updating error status and exit MRC #ifdef SIM // enable Ctrl-C handling for(;;) delay_n(100); #else DEAD_LOOP(); #endif } } void training_message( uint8_t channel, uint8_t rank, uint8_t byte_lane) { // send message to UART DPF(D_INFO, "CH%01X RK%01X BL%01X\n", channel, rank, byte_lane); return; } void print_timings( MRCParams_t *mrc_params) { uint8_t algo_i; uint8_t channel_i; uint8_t rank_i; uint8_t bl_i; uint8_t bl_divisor = (mrc_params->channel_width == x16) ? 2 : 1; DPF(D_INFO, "\n---------------------------"); DPF(D_INFO, "\nALGO[CH:RK] BL0 BL1 BL2 BL3"); DPF(D_INFO, "\n==========================="); for (algo_i = 0; algo_i < eMAX_ALGOS; algo_i++) { for (channel_i = 0; channel_i < NUM_CHANNELS; channel_i++) { if (mrc_params->channel_enables & (1 << channel_i)) { for (rank_i = 0; rank_i < NUM_RANKS; rank_i++) { if (mrc_params->rank_enables & (1 << rank_i)) { switch (algo_i) { case eRCVN: DPF(D_INFO, "\nRCVN[%02d:%02d]", channel_i, rank_i); break; case eWDQS: DPF(D_INFO, "\nWDQS[%02d:%02d]", channel_i, rank_i); break; case eWDQx: DPF(D_INFO, "\nWDQx[%02d:%02d]", channel_i, rank_i); break; case eRDQS: DPF(D_INFO, "\nRDQS[%02d:%02d]", channel_i, rank_i); break; case eVREF: DPF(D_INFO, "\nVREF[%02d:%02d]", channel_i, rank_i); break; case eWCMD: DPF(D_INFO, "\nWCMD[%02d:%02d]", channel_i, rank_i); break; case eWCTL: DPF(D_INFO, "\nWCTL[%02d:%02d]", channel_i, rank_i); break; case eWCLK: DPF(D_INFO, "\nWCLK[%02d:%02d]", channel_i, rank_i); break; default: break; } // algo_i switch for (bl_i = 0; bl_i < (NUM_BYTE_LANES / bl_divisor); bl_i++) { switch (algo_i) { case eRCVN: DPF(D_INFO, " %03d", get_rcvn(channel_i, rank_i, bl_i)); break; case eWDQS: DPF(D_INFO, " %03d", get_wdqs(channel_i, rank_i, bl_i)); break; case eWDQx: DPF(D_INFO, " %03d", get_wdq(channel_i, rank_i, bl_i)); break; case eRDQS: DPF(D_INFO, " %03d", get_rdqs(channel_i, rank_i, bl_i)); break; case eVREF: DPF(D_INFO, " %03d", get_vref(channel_i, bl_i)); break; case eWCMD: DPF(D_INFO, " %03d", get_wcmd(channel_i)); break; case eWCTL: DPF(D_INFO, " %03d", get_wctl(channel_i, rank_i)); break; case eWCLK: DPF(D_INFO, " %03d", get_wclk(channel_i, rank_i)); break; default: break; } // algo_i switch } // bl_i loop } // if rank_i enabled } // rank_i loop } // if channel_i enabled } // channel_i loop } // algo_i loop DPF(D_INFO, "\n---------------------------"); DPF(D_INFO, "\n"); return; } // 32 bit LFSR with characteristic polynomial: X^32 + X^22 +X^2 + X^1 // The function takes pointer to previous 32 bit value and modifies it to next value. void lfsr32( uint32_t *lfsr_ptr) { uint32_t bit; uint32_t lfsr; uint32_t i; lfsr = *lfsr_ptr; for (i = 0; i < 32; i++) { bit = 1 ^ (lfsr & BIT0); bit = bit ^ ((lfsr & BIT1) >> 1); bit = bit ^ ((lfsr & BIT2) >> 2); bit = bit ^ ((lfsr & BIT22) >> 22); lfsr = ((lfsr >> 1) | (bit << 31)); } *lfsr_ptr = lfsr; return; } // The purpose of this function is to ensure the SEC comes out of reset // and IA initiates the SEC enabling Memory Scrambling. void enable_scrambling( MRCParams_t *mrc_params) { uint32_t lfsr = 0; uint8_t i; if (mrc_params->scrambling_enables == 0) return; ENTERFN(); // 32 bit seed is always stored in BIOS NVM. lfsr = mrc_params->timings.scrambler_seed; if (mrc_params->boot_mode == bmCold) { // factory value is 0 and in first boot, a clock based seed is loaded. if (lfsr == 0) { lfsr = read_tsc() & 0x0FFFFFFF; // get seed from system clock and make sure it is not all 1's } // need to replace scrambler // get next 32bit LFSR 16 times which is the last part of the previous scrambler vector. else { for (i = 0; i < 16; i++) { lfsr32(&lfsr); } } mrc_params->timings.scrambler_seed = lfsr; // save new seed. } // if (cold_boot) // In warm boot or S3 exit, we have the previous seed. // In cold boot, we have the last 32bit LFSR which is the new seed. lfsr32(&lfsr); // shift to next value isbW32m(MCU, SCRMSEED, (lfsr & 0x0003FFFF)); for (i = 0; i < 2; i++) { isbW32m(MCU, SCRMLO + i, (lfsr & 0xAAAAAAAA)); } LEAVEFN(); return; } // This function will store relevant timing data // This data will be used on subsequent boots to speed up boot times // and is required for Suspend To RAM capabilities. void store_timings( MRCParams_t *mrc_params) { uint8_t ch, rk, bl; MrcTimings_t *mt = &mrc_params->timings; for (ch = 0; ch < NUM_CHANNELS; ch++) { for (rk = 0; rk < NUM_RANKS; rk++) { for (bl = 0; bl < NUM_BYTE_LANES; bl++) { mt->rcvn[ch][rk][bl] = get_rcvn(ch, rk, bl); // RCVN mt->rdqs[ch][rk][bl] = get_rdqs(ch, rk, bl); // RDQS mt->wdqs[ch][rk][bl] = get_wdqs(ch, rk, bl); // WDQS mt->wdq[ch][rk][bl] = get_wdq(ch, rk, bl); // WDQ if (rk == 0) { mt->vref[ch][bl] = get_vref(ch, bl); // VREF (RANK0 only) } } mt->wctl[ch][rk] = get_wctl(ch, rk); // WCTL } mt->wcmd[ch] = get_wcmd(ch); // WCMD } // need to save for a case of changing frequency after warm reset mt->ddr_speed = mrc_params->ddr_speed; return; } // This function will retrieve relevant timing data // This data will be used on subsequent boots to speed up boot times // and is required for Suspend To RAM capabilities. void restore_timings( MRCParams_t *mrc_params) { uint8_t ch, rk, bl; const MrcTimings_t *mt = &mrc_params->timings; for (ch = 0; ch < NUM_CHANNELS; ch++) { for (rk = 0; rk < NUM_RANKS; rk++) { for (bl = 0; bl < NUM_BYTE_LANES; bl++) { set_rcvn(ch, rk, bl, mt->rcvn[ch][rk][bl]); // RCVN set_rdqs(ch, rk, bl, mt->rdqs[ch][rk][bl]); // RDQS set_wdqs(ch, rk, bl, mt->wdqs[ch][rk][bl]); // WDQS set_wdq(ch, rk, bl, mt->wdq[ch][rk][bl]); // WDQ if (rk == 0) { set_vref(ch, bl, mt->vref[ch][bl]); // VREF (RANK0 only) } } set_wctl(ch, rk, mt->wctl[ch][rk]); // WCTL } set_wcmd(ch, mt->wcmd[ch]); // WCMD } return; } // Configure default settings normally set as part of read training // Some defaults have to be set earlier as they may affect earlier // training steps. void default_timings( MRCParams_t *mrc_params) { uint8_t ch, rk, bl; for (ch = 0; ch < NUM_CHANNELS; ch++) { for (rk = 0; rk < NUM_RANKS; rk++) { for (bl = 0; bl < NUM_BYTE_LANES; bl++) { set_rdqs(ch, rk, bl, 24); // RDQS if (rk == 0) { set_vref(ch, bl, 32); // VREF (RANK0 only) } } } } return; }