+++ /dev/null
-// SPDX-License-Identifier: GPL-2.0+ OR BSD-3-Clause
-/*
- * Copyright (C) 2019, STMicroelectronics - All Rights Reserved
- */
-
-#define LOG_CATEGORY UCLASS_RAM
-
-#include <common.h>
-#include <console.h>
-#include <clk.h>
-#include <log.h>
-#include <ram.h>
-#include <rand.h>
-#include <reset.h>
-#include <asm/io.h>
-#include <linux/bitops.h>
-#include <linux/delay.h>
-#include <linux/iopoll.h>
-
-#include "stm32mp1_ddr_regs.h"
-#include "stm32mp1_ddr.h"
-#include "stm32mp1_tests.h"
-
-#define MAX_DQS_PHASE_IDX _144deg
-#define MAX_DQS_UNIT_IDX 7
-#define MAX_GSL_IDX 5
-#define MAX_GPS_IDX 3
-
-/* Number of bytes used in this SW. ( min 1--> max 4). */
-#define NUM_BYTES 4
-
-enum dqs_phase_enum {
- _36deg = 0,
- _54deg = 1,
- _72deg = 2,
- _90deg = 3,
- _108deg = 4,
- _126deg = 5,
- _144deg = 6
-};
-
-/* BIST Result struct */
-struct BIST_result {
- /* Overall test result:
- * 0 Fail (any bit failed) ,
- * 1 Success (All bits success)
- */
- bool test_result;
- /* 1: true, all fail / 0: False, not all bits fail */
- bool all_bits_fail;
- bool bit_i_test_result[8]; /* 0 fail / 1 success */
-};
-
-/* a struct that defines tuning parameters of a byte. */
-struct tuning_position {
- u8 phase; /* DQS phase */
- u8 unit; /* DQS unit delay */
- u32 bits_delay; /* Bits deskew in this byte */
-};
-
-/* 36deg, 54deg, 72deg, 90deg, 108deg, 126deg, 144deg */
-const u8 dx_dll_phase[7] = {3, 2, 1, 0, 14, 13, 12};
-
-static u8 BIST_error_max = 1;
-static u32 BIST_seed = 0x1234ABCD;
-
-static u8 get_nb_bytes(struct stm32mp1_ddrctl *ctl)
-{
- u32 data_bus = readl(&ctl->mstr) & DDRCTRL_MSTR_DATA_BUS_WIDTH_MASK;
- u8 nb_bytes = NUM_BYTES;
-
- switch (data_bus) {
- case DDRCTRL_MSTR_DATA_BUS_WIDTH_HALF:
- nb_bytes /= 2;
- break;
- case DDRCTRL_MSTR_DATA_BUS_WIDTH_QUARTER:
- nb_bytes /= 4;
- break;
- default:
- break;
- }
-
- return nb_bytes;
-}
-
-static u8 get_nb_bank(struct stm32mp1_ddrctl *ctl)
-{
- /* Count bank address bits */
- u8 bits = 0;
- u32 reg, val;
-
- reg = readl(&ctl->addrmap1);
- /* addrmap1.addrmap_bank_b1 */
- val = (reg & GENMASK(5, 0)) >> 0;
- if (val <= 31)
- bits++;
- /* addrmap1.addrmap_bank_b2 */
- val = (reg & GENMASK(13, 8)) >> 8;
- if (val <= 31)
- bits++;
- /* addrmap1.addrmap_bank_b3 */
- val = (reg & GENMASK(21, 16)) >> 16;
- if (val <= 31)
- bits++;
-
- return bits;
-}
-
-static u8 get_nb_col(struct stm32mp1_ddrctl *ctl)
-{
- u8 bits;
- u32 reg, val;
-
- /* Count column address bits, start at 2 for b0 and b1 (fixed) */
- bits = 2;
-
- reg = readl(&ctl->addrmap2);
- /* addrmap2.addrmap_col_b2 */
- val = (reg & GENMASK(3, 0)) >> 0;
- if (val <= 7)
- bits++;
- /* addrmap2.addrmap_col_b3 */
- val = (reg & GENMASK(11, 8)) >> 8;
- if (val <= 7)
- bits++;
- /* addrmap2.addrmap_col_b4 */
- val = (reg & GENMASK(19, 16)) >> 16;
- if (val <= 7)
- bits++;
- /* addrmap2.addrmap_col_b5 */
- val = (reg & GENMASK(27, 24)) >> 24;
- if (val <= 7)
- bits++;
-
- reg = readl(&ctl->addrmap3);
- /* addrmap3.addrmap_col_b6 */
- val = (reg & GENMASK(3, 0)) >> 0;
- if (val <= 7)
- bits++;
- /* addrmap3.addrmap_col_b7 */
- val = (reg & GENMASK(11, 8)) >> 8;
- if (val <= 7)
- bits++;
- /* addrmap3.addrmap_col_b8 */
- val = (reg & GENMASK(19, 16)) >> 16;
- if (val <= 7)
- bits++;
- /* addrmap3.addrmap_col_b9 */
- val = (reg & GENMASK(27, 24)) >> 24;
- if (val <= 7)
- bits++;
-
- reg = readl(&ctl->addrmap4);
- /* addrmap4.addrmap_col_b10 */
- val = (reg & GENMASK(3, 0)) >> 0;
- if (val <= 7)
- bits++;
- /* addrmap4.addrmap_col_b11 */
- val = (reg & GENMASK(11, 8)) >> 8;
- if (val <= 7)
- bits++;
-
- return bits;
-}
-
-static u8 get_nb_row(struct stm32mp1_ddrctl *ctl)
-{
- /* Count row address bits */
- u8 bits = 0;
- u32 reg, val;
-
- reg = readl(&ctl->addrmap5);
- /* addrmap5.addrmap_row_b0 */
- val = (reg & GENMASK(3, 0)) >> 0;
- if (val <= 11)
- bits++;
- /* addrmap5.addrmap_row_b1 */
- val = (reg & GENMASK(11, 8)) >> 8;
- if (val <= 11)
- bits++;
- /* addrmap5.addrmap_row_b2_10 */
- val = (reg & GENMASK(19, 16)) >> 16;
- if (val <= 11)
- bits += 9;
- else
- printf("warning: addrmap5.addrmap_row_b2_10 not supported\n");
- /* addrmap5.addrmap_row_b11 */
- val = (reg & GENMASK(27, 24)) >> 24;
- if (val <= 11)
- bits++;
-
- reg = readl(&ctl->addrmap6);
- /* addrmap6.addrmap_row_b12 */
- val = (reg & GENMASK(3, 0)) >> 0;
- if (val <= 7)
- bits++;
- /* addrmap6.addrmap_row_b13 */
- val = (reg & GENMASK(11, 8)) >> 8;
- if (val <= 7)
- bits++;
- /* addrmap6.addrmap_row_b14 */
- val = (reg & GENMASK(19, 16)) >> 16;
- if (val <= 7)
- bits++;
- /* addrmap6.addrmap_row_b15 */
- val = (reg & GENMASK(27, 24)) >> 24;
- if (val <= 7)
- bits++;
-
- return bits;
-}
-
-static void itm_soft_reset(struct stm32mp1_ddrphy *phy)
-{
- stm32mp1_ddrphy_init(phy, DDRPHYC_PIR_ITMSRST);
-}
-
-/* Read DQ unit delay register and provides the retrieved value for DQS
- * We are assuming that we have the same delay when clocking
- * by DQS and when clocking by DQSN
- */
-static u8 DQ_unit_index(struct stm32mp1_ddrphy *phy, u8 byte, u8 bit)
-{
- u32 index;
- u32 addr = DXNDQTR(phy, byte);
-
- /* We are assuming that we have the same delay when clocking by DQS
- * and when clocking by DQSN : use only the low bits
- */
- index = (readl(addr) >> DDRPHYC_DXNDQTR_DQDLY_SHIFT(bit))
- & DDRPHYC_DXNDQTR_DQDLY_LOW_MASK;
-
- log_debug("[%x]: %x => DQ unit index = %x\n", addr, readl(addr), index);
-
- return index;
-}
-
-/* Sets the DQS phase delay for a byte lane.
- *phase delay is specified by giving the index of the desired delay
- * in the dx_dll_phase array.
- */
-static void DQS_phase_delay(struct stm32mp1_ddrphy *phy, u8 byte, u8 phase_idx)
-{
- u8 sdphase_val = 0;
-
- /* Write DXNDLLCR.SDPHASE = dx_dll_phase(phase_index); */
- sdphase_val = dx_dll_phase[phase_idx];
- clrsetbits_le32(DXNDLLCR(phy, byte),
- DDRPHYC_DXNDLLCR_SDPHASE_MASK,
- sdphase_val << DDRPHYC_DXNDLLCR_SDPHASE_SHIFT);
-}
-
-/* Sets the DQS unit delay for a byte lane.
- * unit delay is specified by giving the index of the desired delay
- * for dgsdly and dqsndly (same value).
- */
-static void DQS_unit_delay(struct stm32mp1_ddrphy *phy,
- u8 byte, u8 unit_dly_idx)
-{
- /* Write the same value in DXNDQSTR.DQSDLY and DXNDQSTR.DQSNDLY */
- clrsetbits_le32(DXNDQSTR(phy, byte),
- DDRPHYC_DXNDQSTR_DQSDLY_MASK |
- DDRPHYC_DXNDQSTR_DQSNDLY_MASK,
- (unit_dly_idx << DDRPHYC_DXNDQSTR_DQSDLY_SHIFT) |
- (unit_dly_idx << DDRPHYC_DXNDQSTR_DQSNDLY_SHIFT));
-
- /* After changing this value, an ITM soft reset (PIR.ITMSRST=1,
- * plus PIR.INIT=1) must be issued.
- */
- stm32mp1_ddrphy_init(phy, DDRPHYC_PIR_ITMSRST);
-}
-
-/* Sets the DQ unit delay for a bit line in particular byte lane.
- * unit delay is specified by giving the desired delay
- */
-static void set_DQ_unit_delay(struct stm32mp1_ddrphy *phy,
- u8 byte, u8 bit,
- u8 dq_delay_index)
-{
- u8 dq_bit_delay_val = dq_delay_index | (dq_delay_index << 2);
-
- /* same value on delay for clock DQ an DQS_b */
- clrsetbits_le32(DXNDQTR(phy, byte),
- DDRPHYC_DXNDQTR_DQDLY_MASK
- << DDRPHYC_DXNDQTR_DQDLY_SHIFT(bit),
- dq_bit_delay_val << DDRPHYC_DXNDQTR_DQDLY_SHIFT(bit));
-}
-
-static void set_r0dgsl_delay(struct stm32mp1_ddrphy *phy,
- u8 byte, u8 r0dgsl_idx)
-{
- clrsetbits_le32(DXNDQSTR(phy, byte),
- DDRPHYC_DXNDQSTR_R0DGSL_MASK,
- r0dgsl_idx << DDRPHYC_DXNDQSTR_R0DGSL_SHIFT);
-}
-
-static void set_r0dgps_delay(struct stm32mp1_ddrphy *phy,
- u8 byte, u8 r0dgps_idx)
-{
- clrsetbits_le32(DXNDQSTR(phy, byte),
- DDRPHYC_DXNDQSTR_R0DGPS_MASK,
- r0dgps_idx << DDRPHYC_DXNDQSTR_R0DGPS_SHIFT);
-}
-
-/* Basic BIST configuration for data lane tests. */
-static void config_BIST(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy)
-{
- u8 nb_bank = get_nb_bank(ctl);
- u8 nb_row = get_nb_row(ctl);
- u8 nb_col = get_nb_col(ctl);
-
- /* Selects the SDRAM bank address to be used during BIST. */
- u32 bbank = 0;
- /* Selects the SDRAM row address to be used during BIST. */
- u32 brow = 0;
- /* Selects the SDRAM column address to be used during BIST. */
- u32 bcol = 0;
- /* Selects the value by which the SDRAM address is incremented
- * for each write/read access.
- */
- u32 bainc = 0x00000008;
- /* Specifies the maximum SDRAM rank to be used during BIST.
- * The default value is set to maximum ranks minus 1.
- * must be 0 with single rank
- */
- u32 bmrank = 0;
- /* Selects the SDRAM rank to be used during BIST.
- * must be 0 with single rank
- */
- u32 brank = 0;
-
- /* Specifies the maximum SDRAM bank address to be used during
- * BIST before the address & increments to the next rank.
- */
- u32 bmbank = (1 << nb_bank) - 1;
- /* Specifies the maximum SDRAM row address to be used during
- * BIST before the address & increments to the next bank.
- */
- u32 bmrow = (1 << nb_row) - 1;
- /* Specifies the maximum SDRAM column address to be used during
- * BIST before the address & increments to the next row.
- */
- u32 bmcol = (1 << nb_col) - 1;
-
- u32 bmode_conf = 0x00000001; /* DRam mode */
- u32 bdxen_conf = 0x00000001; /* BIST on Data byte */
- u32 bdpat_conf = 0x00000002; /* Select LFSR pattern */
-
- /*Setup BIST for DRAM mode, and LFSR-random data pattern.*/
- /*Write BISTRR.BMODE = 1?b1;*/
- /*Write BISTRR.BDXEN = 1?b1;*/
- /*Write BISTRR.BDPAT = 2?b10;*/
-
- /* reset BIST */
- writel(0x3, &phy->bistrr);
-
- writel((bmode_conf << 3) | (bdxen_conf << 14) | (bdpat_conf << 17),
- &phy->bistrr);
-
- /*Setup BIST Word Count*/
- /*Write BISTWCR.BWCNT = 16?b0008;*/
- writel(0x00000200, &phy->bistwcr); /* A multiple of BL/2 */
-
- writel(bcol | (brow << 12) | (bbank << 28), &phy->bistar0);
- writel(brank | (bmrank << 2) | (bainc << 4), &phy->bistar1);
- writel(bmcol | (bmrow << 12) | (bmbank << 28), &phy->bistar2);
-}
-
-/* Select the Byte lane to be tested by BIST. */
-static void BIST_datx8_sel(struct stm32mp1_ddrphy *phy, u8 datx8)
-{
- clrsetbits_le32(&phy->bistrr,
- DDRPHYC_BISTRR_BDXSEL_MASK,
- datx8 << DDRPHYC_BISTRR_BDXSEL_SHIFT);
-
- /*(For example, selecting Byte Lane 3, BISTRR.BDXSEL = 4?b0011)*/
- /* Write BISTRR.BDXSEL = datx8; */
-}
-
-/* Perform BIST Write_Read test on a byte lane and return test result. */
-static void BIST_test(struct stm32mp1_ddrphy *phy, u8 byte,
- struct BIST_result *bist)
-{
- bool result = true; /* BIST_SUCCESS */
- u32 cnt = 0;
- u32 error = 0;
- u32 val;
- int ret;
-
- bist->test_result = true;
-
-run:
- itm_soft_reset(phy);
-
- /*Perform BIST Reset*/
- /* Write BISTRR.BINST = 3?b011; */
- clrsetbits_le32(&phy->bistrr,
- 0x00000007,
- 0x00000003);
-
- /*Re-seed LFSR*/
- /* Write BISTLSR.SEED = 32'h1234ABCD; */
- if (BIST_seed)
- writel(BIST_seed, &phy->bistlsr);
- else
- writel(rand(), &phy->bistlsr);
-
- /* some delay to reset BIST */
- udelay(10);
-
- /*Perform BIST Run*/
- clrsetbits_le32(&phy->bistrr,
- 0x00000007,
- 0x00000001);
- /* Write BISTRR.BINST = 3?b001; */
-
- /* poll on BISTGSR.BDONE and wait max 1000 us */
- ret = readl_poll_timeout(&phy->bistgsr, val,
- val & DDRPHYC_BISTGSR_BDDONE, 1000);
-
- if (ret < 0) {
- printf("warning: BIST timeout\n");
- result = false; /* BIST_FAIL; */
- /*Perform BIST Stop */
- clrsetbits_le32(&phy->bistrr, 0x00000007, 0x00000002);
- } else {
- /*Check if received correct number of words*/
- /* if (Read BISTWCSR.DXWCNT = Read BISTWCR.BWCNT) */
- if (((readl(&phy->bistwcsr)) >> DDRPHYC_BISTWCSR_DXWCNT_SHIFT)
- == readl(&phy->bistwcr)) {
- /*Determine if there is a data comparison error*/
- /* if (Read BISTGSR.BDXERR = 1?b0) */
- if (readl(&phy->bistgsr) & DDRPHYC_BISTGSR_BDXERR)
- result = false; /* BIST_FAIL; */
- else
- result = true; /* BIST_SUCCESS; */
- } else {
- result = false; /* BIST_FAIL; */
- }
- }
-
- /* loop while success */
- cnt++;
- if (result && cnt != 1000)
- goto run;
-
- if (!result)
- error++;
-
- if (error < BIST_error_max) {
- if (cnt != 1000)
- goto run;
- bist->test_result = true;
- } else {
- bist->test_result = false;
- }
-}
-
-/* After running the deskew algo, this function applies the new DQ delays
- * by reading them from the array "deskew_delay"and writing in PHY registers.
- * The bits that are not deskewed parfectly (too much skew on them,
- * or data eye very wide) are marked in the array deskew_non_converge.
- */
-static void apply_deskew_results(struct stm32mp1_ddrphy *phy, u8 byte,
- u8 deskew_delay[NUM_BYTES][8],
- u8 deskew_non_converge[NUM_BYTES][8])
-{
- u8 bit_i;
- u8 index;
-
- for (bit_i = 0; bit_i < 8; bit_i++) {
- set_DQ_unit_delay(phy, byte, bit_i, deskew_delay[byte][bit_i]);
- index = DQ_unit_index(phy, byte, bit_i);
- log_debug("Byte %d ; bit %d : The new DQ delay (%d) index=%d [delta=%d, 3 is the default]",
- byte, bit_i, deskew_delay[byte][bit_i],
- index, index - 3);
- printf("Byte %d, bit %d, DQ delay = %d",
- byte, bit_i, deskew_delay[byte][bit_i]);
- if (deskew_non_converge[byte][bit_i] == 1)
- log_debug(" - not converged : still more skew");
- printf("\n");
- }
-}
-
-/* DQ Bit de-skew algorithm.
- * Deskews data lines as much as possible.
- * 1. Add delay to DQS line until finding the failure
- * (normally a hold time violation)
- * 2. Reduce DQS line by small steps until finding the very first time
- * we go back to "Pass" condition.
- * 3. For each DQ line, Reduce DQ delay until finding the very first failure
- * (normally a hold time fail)
- * 4. When all bits are at their first failure delay, we can consider them
- * aligned.
- * Handle conrer situation (Can't find Pass-fail, or fail-pass transitions
- * at any step)
- * TODO Provide a return Status. Improve doc
- */
-static enum test_result bit_deskew(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy, char *string)
-{
- /* New DQ delay value (index), set during Deskew algo */
- u8 deskew_delay[NUM_BYTES][8];
- /*If there is still skew on a bit, mark this bit. */
- u8 deskew_non_converge[NUM_BYTES][8];
- struct BIST_result result;
- s8 dqs_unit_delay_index = 0;
- u8 datx8 = 0;
- u8 bit_i = 0;
- s8 phase_idx = 0;
- s8 bit_i_delay_index = 0;
- u8 success = 0;
- struct tuning_position last_right_ok;
- u8 force_stop = 0;
- u8 fail_found;
- u8 error = 0;
- u8 nb_bytes = get_nb_bytes(ctl);
- /* u8 last_pass_dqs_unit = 0; */
-
- memset(deskew_delay, 0, sizeof(deskew_delay));
- memset(deskew_non_converge, 0, sizeof(deskew_non_converge));
-
- /*Disable DQS Drift Compensation*/
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_DFTCMP);
- /*Disable all bytes*/
- /* Disable automatic power down of DLL and IOs when disabling
- * a byte (To avoid having to add programming and delay
- * for a DLL re-lock when later re-enabling a disabled Byte Lane)
- */
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_PDDISDX);
-
- /* Disable all data bytes */
- clrbits_le32(&phy->dx0gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx1gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx2gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx3gcr, DDRPHYC_DXNGCR_DXEN);
-
- /* Config the BIST block */
- config_BIST(ctl, phy);
- log_debug("BIST Config done.\n");
-
- /* Train each byte */
- for (datx8 = 0; datx8 < nb_bytes; datx8++) {
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- datx8 + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- log_debug("\n======================\n");
- log_debug("Start deskew byte %d .\n", datx8);
- log_debug("======================\n");
- /* Enable Byte (DXNGCR, bit DXEN) */
- setbits_le32(DXNGCR(phy, datx8), DDRPHYC_DXNGCR_DXEN);
-
- /* Select the byte lane for comparison of read data */
- BIST_datx8_sel(phy, datx8);
-
- /* Set all DQDLYn to maximum value. All bits within the byte
- * will be delayed with DQSTR = 2 instead of max = 3
- * to avoid inter bits fail influence
- */
- writel(0xAAAAAAAA, DXNDQTR(phy, datx8));
-
- /* Set the DQS phase delay to 90 DEG (default).
- * What is defined here is the index of the desired config
- * in the PHASE array.
- */
- phase_idx = _90deg;
-
- /* Set DQS unit delay to the max value. */
- dqs_unit_delay_index = MAX_DQS_UNIT_IDX;
- DQS_unit_delay(phy, datx8, dqs_unit_delay_index);
- DQS_phase_delay(phy, datx8, phase_idx);
-
- /* Issue a DLL soft reset */
- clrbits_le32(DXNDLLCR(phy, datx8), DDRPHYC_DXNDLLCR_DLLSRST);
- setbits_le32(DXNDLLCR(phy, datx8), DDRPHYC_DXNDLLCR_DLLSRST);
-
- /* Test this typical init condition */
- BIST_test(phy, datx8, &result);
- success = result.test_result;
-
- /* If the test pass in this typical condition,
- * start the algo with it.
- * Else, look for Pass init condition
- */
- if (!success) {
- log_debug("Fail at init condtion. Let's look for a good init condition.\n");
- success = 0; /* init */
- /* Make sure we start with a PASS condition before
- * looking for a fail condition.
- * Find the first PASS PHASE condition
- */
-
- /* escape if we find a PASS */
- log_debug("increase Phase idx\n");
- while (!success && (phase_idx <= MAX_DQS_PHASE_IDX)) {
- DQS_phase_delay(phy, datx8, phase_idx);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- phase_idx++;
- }
- /* if ended with success
- * ==>> Restore the fist success condition
- */
- if (success)
- phase_idx--; /* because it ended with ++ */
- }
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- datx8 + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- /* We couldn't find a successful condition, its seems
- * we have hold violation, lets try reduce DQS_unit Delay
- */
- if (!success) {
- /* We couldn't find a successful condition, its seems
- * we have hold violation, lets try reduce DQS_unit
- * Delay
- */
- log_debug("Still fail. Try decrease DQS Unit delay\n");
-
- phase_idx = 0;
- dqs_unit_delay_index = 0;
- DQS_phase_delay(phy, datx8, phase_idx);
-
- /* escape if we find a PASS */
- while (!success &&
- (dqs_unit_delay_index <=
- MAX_DQS_UNIT_IDX)) {
- DQS_unit_delay(phy, datx8,
- dqs_unit_delay_index);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- dqs_unit_delay_index++;
- }
- if (success) {
- /* Restore the first success condition*/
- dqs_unit_delay_index--;
- /* last_pass_dqs_unit = dqs_unit_delay_index;*/
- DQS_unit_delay(phy, datx8,
- dqs_unit_delay_index);
- } else {
- /* No need to continue,
- * there is no pass region.
- */
- force_stop = 1;
- }
- }
-
- /* There is an initial PASS condition
- * Look for the first failing condition by PHASE stepping.
- * This part of the algo can finish without converging.
- */
- if (force_stop) {
- printf("Result: Failed ");
- printf("[Cannot Deskew lines, ");
- printf("there is no PASS region]\n");
- error++;
- continue;
- }
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- datx8 + 1, nb_bytes, error);
- return TEST_FAILED;
- }
-
- log_debug("there is a pass region for phase idx %d\n",
- phase_idx);
- log_debug("Step1: Find the first failing condition\n");
- /* Look for the first failing condition by PHASE stepping.
- * This part of the algo can finish without converging.
- */
-
- /* escape if we find a fail (hold time violation)
- * condition at any bit or if out of delay range.
- */
- while (success && (phase_idx <= MAX_DQS_PHASE_IDX)) {
- DQS_phase_delay(phy, datx8, phase_idx);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- phase_idx++;
- }
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- datx8 + 1, nb_bytes, error);
- return TEST_FAILED;
- }
-
- /* if the loop ended with a failing condition at any bit,
- * lets look for the first previous success condition by unit
- * stepping (minimal delay)
- */
- if (!success) {
- log_debug("Fail region (PHASE) found phase idx %d\n",
- phase_idx);
- log_debug("Let's look for first success by DQS Unit steps\n");
- /* This part, the algo always converge */
- phase_idx--;
-
- /* escape if we find a success condition
- * or if out of delay range.
- */
- while (!success && dqs_unit_delay_index >= 0) {
- DQS_unit_delay(phy, datx8,
- dqs_unit_delay_index);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- dqs_unit_delay_index--;
- }
- /* if the loop ended with a success condition,
- * the last delay Right OK (before hold violation)
- * condition is then defined as following:
- */
- if (success) {
- /* Hold the dely parameters of the the last
- * delay Right OK condition.
- * -1 to get back to current condition
- */
- last_right_ok.phase = phase_idx;
- /*+1 to get back to current condition */
- last_right_ok.unit = dqs_unit_delay_index + 1;
- last_right_ok.bits_delay = 0xFFFFFFFF;
- log_debug("Found %d\n", dqs_unit_delay_index);
- } else {
- /* the last OK condition is then with the
- * previous phase_idx.
- * -2 instead of -1 because at the last
- * iteration of the while(),
- * we incremented phase_idx
- */
- last_right_ok.phase = phase_idx - 1;
- /* Nominal+1. Because we want the previous
- * delay after reducing the phase delay.
- */
- last_right_ok.unit = 1;
- last_right_ok.bits_delay = 0xFFFFFFFF;
- log_debug("Not Found : try previous phase %d\n",
- phase_idx - 1);
-
- DQS_phase_delay(phy, datx8, phase_idx - 1);
- dqs_unit_delay_index = 0;
- success = true;
- while (success &&
- (dqs_unit_delay_index <
- MAX_DQS_UNIT_IDX)) {
- DQS_unit_delay(phy, datx8,
- dqs_unit_delay_index);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- dqs_unit_delay_index++;
- log_debug("dqs_unit_delay_index = %d, result = %d\n",
- dqs_unit_delay_index, success);
- }
-
- if (!success) {
- last_right_ok.unit =
- dqs_unit_delay_index - 1;
- } else {
- last_right_ok.unit = 0;
- log_debug("ERROR: failed region not FOUND");
- }
- }
- } else {
- /* we can't find a failing condition at all bits
- * ==> Just hold the last test condition
- * (the max DQS delay)
- * which is the most likely,
- * the closest to a hold violation
- * If we can't find a Fail condition after
- * the Pass region, stick at this position
- * In order to have max chances to find a fail
- * when reducing DQ delays.
- */
- last_right_ok.phase = MAX_DQS_PHASE_IDX;
- last_right_ok.unit = MAX_DQS_UNIT_IDX;
- last_right_ok.bits_delay = 0xFFFFFFFF;
- log_debug("Can't find the a fail condition\n");
- }
-
- /* step 2:
- * if we arrive at this stage, it means that we found the last
- * Right OK condition (by tweeking the DQS delay). Or we simply
- * pushed DQS delay to the max
- * This means that by reducing the delay on some DQ bits,
- * we should find a failing condition.
- */
- printf("Byte %d, DQS unit = %d, phase = %d\n",
- datx8, last_right_ok.unit, last_right_ok.phase);
- log_debug("Step2, unit = %d, phase = %d, bits delay=%x\n",
- last_right_ok.unit, last_right_ok.phase,
- last_right_ok.bits_delay);
-
- /* Restore the last_right_ok condtion. */
- DQS_unit_delay(phy, datx8, last_right_ok.unit);
- DQS_phase_delay(phy, datx8, last_right_ok.phase);
- writel(last_right_ok.bits_delay, DXNDQTR(phy, datx8));
-
- /* train each bit
- * reduce delay on each bit, and perform a write/read test
- * and stop at the very first time it fails.
- * the goal is the find the first failing condition
- * for each bit.
- * When we achieve this condition< for all the bits,
- * we are sure they are aligned (+/- step resolution)
- */
- fail_found = 0;
- for (bit_i = 0; bit_i < 8; bit_i++) {
- if (ctrlc()) {
- sprintf(string,
- "interrupted at byte %d/%d, error=%d",
- datx8 + 1, nb_bytes, error);
- return error;
- }
- log_debug("deskewing bit %d:\n", bit_i);
- success = 1; /* init */
- /* Set all DQDLYn to maximum value.
- * Only bit_i will be down-delayed
- * ==> if we have a fail, it will be definitely
- * from bit_i
- */
- writel(0xFFFFFFFF, DXNDQTR(phy, datx8));
- /* Arriving at this stage,
- * we have a success condition with delay = 3;
- */
- bit_i_delay_index = 3;
-
- /* escape if bit delay is out of range or
- * if a fatil occurs
- */
- while ((bit_i_delay_index >= 0) && success) {
- set_DQ_unit_delay(phy, datx8,
- bit_i,
- bit_i_delay_index);
- BIST_test(phy, datx8, &result);
- success = result.test_result;
- bit_i_delay_index--;
- }
-
- /* if escape with a fail condition
- * ==> save this position for bit_i
- */
- if (!success) {
- /* save the delay position.
- * Add 1 because the while loop ended with a --,
- * and that we need to hold the last success
- * delay
- */
- deskew_delay[datx8][bit_i] =
- bit_i_delay_index + 2;
- if (deskew_delay[datx8][bit_i] > 3)
- deskew_delay[datx8][bit_i] = 3;
-
- /* A flag that states we found at least a fail
- * at one bit.
- */
- fail_found = 1;
- log_debug("Fail found on bit %d, for delay = %d => deskew[%d][%d] = %d\n",
- bit_i, bit_i_delay_index + 1,
- datx8, bit_i,
- deskew_delay[datx8][bit_i]);
- } else {
- /* if we can find a success condition by
- * back-delaying this bit, just set the delay
- * to 0 (the best deskew
- * possible) and mark the bit.
- */
- deskew_delay[datx8][bit_i] = 0;
- /* set a flag that will be used later
- * in the report.
- */
- deskew_non_converge[datx8][bit_i] = 1;
- log_debug("Fail not found on bit %d => deskew[%d][%d] = %d\n",
- bit_i, datx8, bit_i,
- deskew_delay[datx8][bit_i]);
- }
- }
- log_debug("**********byte %d tuning complete************\n",
- datx8);
- /* If we can't find any failure by back delaying DQ lines,
- * hold the default values
- */
- if (!fail_found) {
- for (bit_i = 0; bit_i < 8; bit_i++)
- deskew_delay[datx8][bit_i] = 0;
- log_debug("The Deskew algorithm can't converge, there is too much margin in your design. Good job!\n");
- }
-
- apply_deskew_results(phy, datx8, deskew_delay,
- deskew_non_converge);
- /* Restore nominal value for DQS delay */
- DQS_phase_delay(phy, datx8, 3);
- DQS_unit_delay(phy, datx8, 3);
- /* disable byte after byte bits deskew */
- clrbits_le32(DXNGCR(phy, datx8), DDRPHYC_DXNGCR_DXEN);
- } /* end of byte deskew */
-
- /* re-enable all data bytes */
- setbits_le32(&phy->dx0gcr, DDRPHYC_DXNGCR_DXEN);
- setbits_le32(&phy->dx1gcr, DDRPHYC_DXNGCR_DXEN);
- setbits_le32(&phy->dx2gcr, DDRPHYC_DXNGCR_DXEN);
- setbits_le32(&phy->dx3gcr, DDRPHYC_DXNGCR_DXEN);
-
- if (error) {
- sprintf(string, "error = %d", error);
- return TEST_FAILED;
- }
-
- return TEST_PASSED;
-} /* end function */
-
-/* Trim DQS timings and set it in the centre of data eye.
- * Look for a PPPPF region, then look for a FPPP region and finally select
- * the mid of the FPPPPPF region
- */
-static enum test_result eye_training(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy, char *string)
-{
- /*Stores the DQS trim values (PHASE index, unit index) */
- u8 eye_training_val[NUM_BYTES][2];
- u8 byte = 0;
- struct BIST_result result;
- s8 dqs_unit_delay_index = 0;
- s8 phase_idx = 0;
- s8 dqs_unit_delay_index_pass = 0;
- s8 phase_idx_pass = 0;
- u8 success = 0;
- u8 left_phase_bound_found, right_phase_bound_found;
- u8 left_unit_bound_found, right_unit_bound_found;
- u8 left_bound_found, right_bound_found;
- struct tuning_position left_bound, right_bound;
- u8 error = 0;
- u8 nb_bytes = get_nb_bytes(ctl);
-
- /*Disable DQS Drift Compensation*/
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_DFTCMP);
- /*Disable all bytes*/
- /* Disable automatic power down of DLL and IOs when disabling a byte
- * (To avoid having to add programming and delay
- * for a DLL re-lock when later re-enabling a disabled Byte Lane)
- */
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_PDDISDX);
-
- /*Disable all data bytes */
- clrbits_le32(&phy->dx0gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx1gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx2gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx3gcr, DDRPHYC_DXNGCR_DXEN);
-
- /* Config the BIST block */
- config_BIST(ctl, phy);
-
- for (byte = 0; byte < nb_bytes; byte++) {
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- byte + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- right_bound.phase = 0;
- right_bound.unit = 0;
-
- left_bound.phase = 0;
- left_bound.unit = 0;
-
- left_phase_bound_found = 0;
- right_phase_bound_found = 0;
-
- left_unit_bound_found = 0;
- right_unit_bound_found = 0;
-
- left_bound_found = 0;
- right_bound_found = 0;
-
- /* Enable Byte (DXNGCR, bit DXEN) */
- setbits_le32(DXNGCR(phy, byte), DDRPHYC_DXNGCR_DXEN);
-
- /* Select the byte lane for comparison of read data */
- BIST_datx8_sel(phy, byte);
-
- /* Set DQS phase delay to the nominal value. */
- phase_idx = _90deg;
- phase_idx_pass = phase_idx;
-
- /* Set DQS unit delay to the nominal value. */
- dqs_unit_delay_index = 3;
- dqs_unit_delay_index_pass = dqs_unit_delay_index;
- success = 0;
-
- log_debug("STEP0: Find Init delay\n");
- /* STEP0: Find Init delay: a delay that put the system
- * in a "Pass" condition then (TODO) update
- * dqs_unit_delay_index_pass & phase_idx_pass
- */
- DQS_unit_delay(phy, byte, dqs_unit_delay_index);
- DQS_phase_delay(phy, byte, phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- /* If we have a fail in the nominal condition */
- if (!success) {
- /* Look at the left */
- while (phase_idx >= 0 && !success) {
- phase_idx--;
- DQS_phase_delay(phy, byte, phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- }
- }
- if (!success) {
- /* if we can't find pass condition,
- * then look at the right
- */
- phase_idx = _90deg;
- while (phase_idx <= MAX_DQS_PHASE_IDX &&
- !success) {
- phase_idx++;
- DQS_phase_delay(phy, byte,
- phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- }
- }
- /* save the pass condition */
- if (success) {
- phase_idx_pass = phase_idx;
- } else {
- printf("Result: Failed ");
- printf("[Cannot DQS timings, ");
- printf("there is no PASS region]\n");
- error++;
- continue;
- }
-
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- byte + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- log_debug("STEP1: Find LEFT PHASE DQS Bound\n");
- /* STEP1: Find LEFT PHASE DQS Bound */
- while ((phase_idx >= 0) &&
- (phase_idx <= MAX_DQS_PHASE_IDX) &&
- !left_phase_bound_found) {
- DQS_unit_delay(phy, byte,
- dqs_unit_delay_index);
- DQS_phase_delay(phy, byte,
- phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
-
- /*TODO: Manage the case were at the beginning
- * there is already a fail
- */
- if (!success) {
- /* the last pass condition */
- left_bound.phase = ++phase_idx;
- left_phase_bound_found = 1;
- } else if (success) {
- phase_idx--;
- }
- }
- if (!left_phase_bound_found) {
- left_bound.phase = 0;
- phase_idx = 0;
- }
- /* If not found, lets take 0 */
-
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- byte + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- log_debug("STEP2: Find UNIT left bound\n");
- /* STEP2: Find UNIT left bound */
- while ((dqs_unit_delay_index >= 0) &&
- !left_unit_bound_found) {
- DQS_unit_delay(phy, byte,
- dqs_unit_delay_index);
- DQS_phase_delay(phy, byte, phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- if (!success) {
- left_bound.unit =
- ++dqs_unit_delay_index;
- left_unit_bound_found = 1;
- left_bound_found = 1;
- } else if (success) {
- dqs_unit_delay_index--;
- }
- }
-
- /* If not found, lets take 0 */
- if (!left_unit_bound_found)
- left_bound.unit = 0;
-
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- byte + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- log_debug("STEP3: Find PHase right bound\n");
- /* STEP3: Find PHase right bound, start with "pass"
- * condition
- */
-
- /* Set DQS phase delay to the pass value. */
- phase_idx = phase_idx_pass;
-
- /* Set DQS unit delay to the pass value. */
- dqs_unit_delay_index = dqs_unit_delay_index_pass;
-
- while ((phase_idx <= MAX_DQS_PHASE_IDX) &&
- !right_phase_bound_found) {
- DQS_unit_delay(phy, byte,
- dqs_unit_delay_index);
- DQS_phase_delay(phy, byte, phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- if (!success) {
- /* the last pass condition */
- right_bound.phase = --phase_idx;
- right_phase_bound_found = 1;
- } else if (success) {
- phase_idx++;
- }
- }
-
- /* If not found, lets take the max value */
- if (!right_phase_bound_found) {
- right_bound.phase = MAX_DQS_PHASE_IDX;
- phase_idx = MAX_DQS_PHASE_IDX;
- }
-
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d, error=%d",
- byte + 1, nb_bytes, error);
- return TEST_FAILED;
- }
- log_debug("STEP4: Find UNIT right bound\n");
- /* STEP4: Find UNIT right bound */
- while ((dqs_unit_delay_index <= MAX_DQS_UNIT_IDX) &&
- !right_unit_bound_found) {
- DQS_unit_delay(phy, byte,
- dqs_unit_delay_index);
- DQS_phase_delay(phy, byte, phase_idx);
- BIST_test(phy, byte, &result);
- success = result.test_result;
- if (!success) {
- right_bound.unit =
- --dqs_unit_delay_index;
- right_unit_bound_found = 1;
- right_bound_found = 1;
- } else if (success) {
- dqs_unit_delay_index++;
- }
- }
- /* If not found, lets take the max value */
- if (!right_unit_bound_found)
- right_bound.unit = MAX_DQS_UNIT_IDX;
-
- /* If we found a regular FAil Pass FAil pattern
- * FFPPPPPPFF
- * OR PPPPPFF Or FFPPPPP
- */
-
- if (left_bound_found || right_bound_found) {
- eye_training_val[byte][0] = (right_bound.phase +
- left_bound.phase) / 2;
- eye_training_val[byte][1] = (right_bound.unit +
- left_bound.unit) / 2;
-
- /* If we already lost 1/2PHASE Tuning,
- * let's try to recover by ++ on unit
- */
- if (((right_bound.phase + left_bound.phase) % 2 == 1) &&
- eye_training_val[byte][1] != MAX_DQS_UNIT_IDX)
- eye_training_val[byte][1]++;
- log_debug("** found phase : %d - %d & unit %d - %d\n",
- right_bound.phase, left_bound.phase,
- right_bound.unit, left_bound.unit);
- log_debug("** calculating mid region: phase: %d unit: %d (nominal is 3)\n",
- eye_training_val[byte][0],
- eye_training_val[byte][1]);
- } else {
- /* PPPPPPPPPP, we're already good.
- * Set nominal values.
- */
- eye_training_val[byte][0] = 3;
- eye_training_val[byte][1] = 3;
- }
- DQS_phase_delay(phy, byte, eye_training_val[byte][0]);
- DQS_unit_delay(phy, byte, eye_training_val[byte][1]);
-
- printf("Byte %d, DQS unit = %d, phase = %d\n",
- byte,
- eye_training_val[byte][1],
- eye_training_val[byte][0]);
- }
-
- if (error) {
- sprintf(string, "error = %d", error);
- return TEST_FAILED;
- }
-
- return TEST_PASSED;
-}
-
-static void display_reg_results(struct stm32mp1_ddrphy *phy, u8 byte)
-{
- u8 i = 0;
-
- printf("Byte %d Dekew result, bit0 delay, bit1 delay...bit8 delay\n ",
- byte);
-
- for (i = 0; i < 8; i++)
- printf("%d ", DQ_unit_index(phy, byte, i));
- printf("\n");
-
- printf("dxndllcr: [%08x] val:%08x\n",
- DXNDLLCR(phy, byte),
- readl(DXNDLLCR(phy, byte)));
- printf("dxnqdstr: [%08x] val:%08x\n",
- DXNDQSTR(phy, byte),
- readl(DXNDQSTR(phy, byte)));
- printf("dxndqtr: [%08x] val:%08x\n",
- DXNDQTR(phy, byte),
- readl(DXNDQTR(phy, byte)));
-}
-
-/* analyse the dgs gating log table, and determine the midpoint.*/
-static u8 set_midpoint_read_dqs_gating(struct stm32mp1_ddrphy *phy, u8 byte,
- u8 dqs_gating[NUM_BYTES]
- [MAX_GSL_IDX + 1]
- [MAX_GPS_IDX + 1])
-{
- /* stores the dqs gate values (gsl index, gps index) */
- u8 dqs_gate_values[NUM_BYTES][2];
- u8 gsl_idx, gps_idx = 0;
- u8 left_bound_idx[2] = {0, 0};
- u8 right_bound_idx[2] = {0, 0};
- u8 left_bound_found = 0;
- u8 right_bound_found = 0;
- u8 intermittent = 0;
- u8 value;
-
- for (gsl_idx = 0; gsl_idx <= MAX_GSL_IDX; gsl_idx++) {
- for (gps_idx = 0; gps_idx <= MAX_GPS_IDX; gps_idx++) {
- value = dqs_gating[byte][gsl_idx][gps_idx];
- if (value == 1 && left_bound_found == 0) {
- left_bound_idx[0] = gsl_idx;
- left_bound_idx[1] = gps_idx;
- left_bound_found = 1;
- } else if (value == 0 &&
- left_bound_found == 1 &&
- !right_bound_found) {
- if (gps_idx == 0) {
- right_bound_idx[0] = gsl_idx - 1;
- right_bound_idx[1] = MAX_GPS_IDX;
- } else {
- right_bound_idx[0] = gsl_idx;
- right_bound_idx[1] = gps_idx - 1;
- }
- right_bound_found = 1;
- } else if (value == 1 &&
- right_bound_found == 1) {
- intermittent = 1;
- }
- }
- }
-
- /* if only ppppppp is found, there is no mid region. */
- if (left_bound_idx[0] == 0 && left_bound_idx[1] == 0 &&
- right_bound_idx[0] == 0 && right_bound_idx[1] == 0)
- intermittent = 1;
-
- /*if we found a regular fail pass fail pattern ffppppppff
- * or pppppff or ffppppp
- */
- if (!intermittent) {
- /*if we found a regular fail pass fail pattern ffppppppff
- * or pppppff or ffppppp
- */
- if (left_bound_found || right_bound_found) {
- log_debug("idx0(%d): %d %d idx1(%d) : %d %d\n",
- left_bound_found,
- right_bound_idx[0], left_bound_idx[0],
- right_bound_found,
- right_bound_idx[1], left_bound_idx[1]);
- dqs_gate_values[byte][0] =
- (right_bound_idx[0] + left_bound_idx[0]) / 2;
- dqs_gate_values[byte][1] =
- (right_bound_idx[1] + left_bound_idx[1]) / 2;
- /* if we already lost 1/2gsl tuning,
- * let's try to recover by ++ on gps
- */
- if (((right_bound_idx[0] +
- left_bound_idx[0]) % 2 == 1) &&
- dqs_gate_values[byte][1] != MAX_GPS_IDX)
- dqs_gate_values[byte][1]++;
- /* if we already lost 1/2gsl tuning and gps is on max*/
- else if (((right_bound_idx[0] +
- left_bound_idx[0]) % 2 == 1) &&
- dqs_gate_values[byte][1] == MAX_GPS_IDX) {
- dqs_gate_values[byte][1] = 0;
- dqs_gate_values[byte][0]++;
- }
- /* if we have gsl left and write limit too close
- * (difference=1)
- */
- if (((right_bound_idx[0] - left_bound_idx[0]) == 1)) {
- dqs_gate_values[byte][1] = (left_bound_idx[1] +
- right_bound_idx[1] +
- 4) / 2;
- if (dqs_gate_values[byte][1] >= 4) {
- dqs_gate_values[byte][0] =
- right_bound_idx[0];
- dqs_gate_values[byte][1] -= 4;
- } else {
- dqs_gate_values[byte][0] =
- left_bound_idx[0];
- }
- }
- log_debug("*******calculating mid region: system latency: %d phase: %d********\n",
- dqs_gate_values[byte][0],
- dqs_gate_values[byte][1]);
- log_debug("*******the nominal values were system latency: 0 phase: 2*******\n");
- }
- } else {
- /* if intermitant, restore defaut values */
- log_debug("dqs gating:no regular fail/pass/fail found. defaults values restored.\n");
- dqs_gate_values[byte][0] = 0;
- dqs_gate_values[byte][1] = 2;
- }
- set_r0dgsl_delay(phy, byte, dqs_gate_values[byte][0]);
- set_r0dgps_delay(phy, byte, dqs_gate_values[byte][1]);
- printf("Byte %d, R0DGSL = %d, R0DGPS = %d\n",
- byte, dqs_gate_values[byte][0], dqs_gate_values[byte][1]);
-
- /* return 0 if intermittent or if both left_bound
- * and right_bound are not found
- */
- return !(intermittent || (left_bound_found && right_bound_found));
-}
-
-static enum test_result read_dqs_gating(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string)
-{
- /* stores the log of pass/fail */
- u8 dqs_gating[NUM_BYTES][MAX_GSL_IDX + 1][MAX_GPS_IDX + 1];
- u8 byte, gsl_idx, gps_idx = 0;
- struct BIST_result result;
- u8 success = 0;
- u8 nb_bytes = get_nb_bytes(ctl);
-
- memset(dqs_gating, 0x0, sizeof(dqs_gating));
-
- /*disable dqs drift compensation*/
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_DFTCMP);
- /*disable all bytes*/
- /* disable automatic power down of dll and ios when disabling a byte
- * (to avoid having to add programming and delay
- * for a dll re-lock when later re-enabling a disabled byte lane)
- */
- clrbits_le32(&phy->pgcr, DDRPHYC_PGCR_PDDISDX);
-
- /* disable all data bytes */
- clrbits_le32(&phy->dx0gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx1gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx2gcr, DDRPHYC_DXNGCR_DXEN);
- clrbits_le32(&phy->dx3gcr, DDRPHYC_DXNGCR_DXEN);
-
- /* config the bist block */
- config_BIST(ctl, phy);
-
- for (byte = 0; byte < nb_bytes; byte++) {
- if (ctrlc()) {
- sprintf(string, "interrupted at byte %d/%d",
- byte + 1, nb_bytes);
- return TEST_FAILED;
- }
- /* enable byte x (dxngcr, bit dxen) */
- setbits_le32(DXNGCR(phy, byte), DDRPHYC_DXNGCR_DXEN);
-
- /* select the byte lane for comparison of read data */
- BIST_datx8_sel(phy, byte);
- for (gsl_idx = 0; gsl_idx <= MAX_GSL_IDX; gsl_idx++) {
- for (gps_idx = 0; gps_idx <= MAX_GPS_IDX; gps_idx++) {
- if (ctrlc()) {
- sprintf(string,
- "interrupted at byte %d/%d",
- byte + 1, nb_bytes);
- return TEST_FAILED;
- }
- /* write cfg to dxndqstr */
- set_r0dgsl_delay(phy, byte, gsl_idx);
- set_r0dgps_delay(phy, byte, gps_idx);
-
- BIST_test(phy, byte, &result);
- success = result.test_result;
- if (success)
- dqs_gating[byte][gsl_idx][gps_idx] = 1;
- itm_soft_reset(phy);
- }
- }
- set_midpoint_read_dqs_gating(phy, byte, dqs_gating);
- /* dummy reads */
- readl(0xc0000000);
- readl(0xc0000000);
- }
-
- /* re-enable drift compensation */
- /* setbits_le32(&phy->pgcr, DDRPHYC_PGCR_DFTCMP); */
- return TEST_PASSED;
-}
-
-/****************************************************************
- * TEST
- ****************************************************************
- */
-static enum test_result do_read_dqs_gating(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string, int argc,
- char *argv[])
-{
- u32 rfshctl3 = readl(&ctl->rfshctl3);
- u32 pwrctl = readl(&ctl->pwrctl);
- u32 derateen = readl(&ctl->derateen);
- enum test_result res;
-
- writel(0x0, &ctl->derateen);
- stm32mp1_refresh_disable(ctl);
-
- res = read_dqs_gating(ctl, phy, string);
-
- stm32mp1_refresh_restore(ctl, rfshctl3, pwrctl);
- writel(derateen, &ctl->derateen);
-
- return res;
-}
-
-static enum test_result do_bit_deskew(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string, int argc, char *argv[])
-{
- u32 rfshctl3 = readl(&ctl->rfshctl3);
- u32 pwrctl = readl(&ctl->pwrctl);
- u32 derateen = readl(&ctl->derateen);
- enum test_result res;
-
- writel(0x0, &ctl->derateen);
- stm32mp1_refresh_disable(ctl);
-
- res = bit_deskew(ctl, phy, string);
-
- stm32mp1_refresh_restore(ctl, rfshctl3, pwrctl);
- writel(derateen, &ctl->derateen);
-
- return res;
-}
-
-static enum test_result do_eye_training(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string, int argc, char *argv[])
-{
- u32 rfshctl3 = readl(&ctl->rfshctl3);
- u32 pwrctl = readl(&ctl->pwrctl);
- u32 derateen = readl(&ctl->derateen);
- enum test_result res;
-
- writel(0x0, &ctl->derateen);
- stm32mp1_refresh_disable(ctl);
-
- res = eye_training(ctl, phy, string);
-
- stm32mp1_refresh_restore(ctl, rfshctl3, pwrctl);
- writel(derateen, &ctl->derateen);
-
- return res;
-}
-
-static enum test_result do_display(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string, int argc, char *argv[])
-{
- int byte;
- u8 nb_bytes = get_nb_bytes(ctl);
-
- for (byte = 0; byte < nb_bytes; byte++)
- display_reg_results(phy, byte);
-
- return TEST_PASSED;
-}
-
-static enum test_result do_bist_config(struct stm32mp1_ddrctl *ctl,
- struct stm32mp1_ddrphy *phy,
- char *string, int argc, char *argv[])
-{
- unsigned long value;
-
- if (argc > 0) {
- if (strict_strtoul(argv[0], 0, &value) < 0) {
- sprintf(string, "invalid nbErr %s", argv[0]);
- return TEST_FAILED;
- }
- BIST_error_max = value;
- }
- if (argc > 1) {
- if (strict_strtoul(argv[1], 0, &value) < 0) {
- sprintf(string, "invalid Seed %s", argv[1]);
- return TEST_FAILED;
- }
- BIST_seed = value;
- }
- printf("Bist.nbErr = %d\n", BIST_error_max);
- if (BIST_seed)
- printf("Bist.Seed = 0x%x\n", BIST_seed);
- else
- printf("Bist.Seed = random\n");
-
- return TEST_PASSED;
-}
-
-/****************************************************************
- * TEST Description
- ****************************************************************
- */
-
-const struct test_desc tuning[] = {
- {do_read_dqs_gating, "Read DQS gating",
- "software read DQS Gating", "", 0 },
- {do_bit_deskew, "Bit de-skew", "", "", 0 },
- {do_eye_training, "Eye Training", "or DQS training", "", 0 },
- {do_display, "Display registers", "", "", 0 },
- {do_bist_config, "Bist config", "[nbErr] [seed]",
- "configure Bist test", 2},
-};
-
-const int tuning_nb = ARRAY_SIZE(tuning);