/* * Copyright (C) 2021-2024, STMicroelectronics - All Rights Reserved * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef MNPMUSRAMMSGBLOCK_LPDDR4_H #define MNPMUSRAMMSGBLOCK_LPDDR4_H /* LPDDR4_1D training firmware message block structure * * Please refer to the Training Firmware App Note for futher information about * the usage for Message Block. */ struct pmu_smb_ddr_1d { uint8_t reserved00; /* * Byte offset 0x00, CSR Addr 0x54000, Direction=In * reserved00[0:4] RFU, must be zero * * reserved00[5] = Quick Rd2D during 1D Training * 0x1 = Read Deskew will begin by enabling and quickly * training the phy's per-lane reference voltages. * Training the vrefDACs CSRs will increase the maximum 1D * training time by around half a millisecond, but will * improve 1D training accuracy on systems with * significant voltage-offsets between lane read eyes. * 0x0 = Read Deskew will assume the messageblock's * phyVref setting is optimal for all lanes. * * reserved00[6] = Enable High Effort WrDQ1D * 0x1 = WrDQ1D will conditionally retry training at * several extra RxClkDly Timings. This will increase the * maximum 1D training time by up to 4 extra iterations of * WrDQ1D. This is only required in systems that suffer * from very large, asymmetric eye-collapse when receiving * PRBS patterns. * 0x0 = WrDQ1D assume rxClkDly values found by SI * Friendly RdDqs1D will work for receiving PRBS patterns * * reserved00[7] = Optimize for the special hard macros in * TSMC28. * 0x1 = set if the phy being trained was manufactured in * any TSMC28 process node. * 0x0 = otherwise, when not training a TSMC28 phy, leave * this field as 0. */ uint8_t msgmisc; /* * Byte offset 0x01, CSR Addr 0x54000, Direction=In * Contains various global options for training. * * Bit fields: * * msgmisc[0] MTESTEnable * 0x1 = Pulse primary digital test output bump at the end * of each major training stage. This enables observation * of training stage completion by observing the digital * test output. * 0x0 = Do not pulse primary digital test output bump * * msgmisc[1] SimulationOnlyReset * 0x1 = Verilog only simulation option to shorten * duration of DRAM reset pulse length to 1ns. * Must never be set to 1 in silicon. * 0x0 = Use reset pulse length specified by JEDEC * standard. * * msgmisc[2] SimulationOnlyTraining * 0x1 = Verilog only simulation option to shorten the * duration of the training steps by performing fewer * iterations. * Must never be set to 1 in silicon. * 0x0 = Use standard training duration. * * msgmisc[3] Disable Boot Clock * 0x1 = Disable boot frequency clock when initializing * DRAM. (not recommended) * 0x0 = Use Boot Frequency Clock * * msgmisc[4] Suppress streaming messages, including * assertions, regardless of hdtctrl setting. * Stage Completion messages, as well as training completion * and error messages are still sent depending on hdtctrl * setting. * * msgmisc[5] PerByteMaxRdLat * 0x1 = Each DBYTE will return dfi_rddata_valid at the * lowest possible latency. This may result in unaligned * data between bytes to be returned to the DFI. * 0x0 = Every DBYTE will return dfi_rddata_valid * simultaneously. This will ensure that data bytes will * return aligned accesses to the DFI. * * msgmisc[7-6] RFU, must be zero * * Notes: * * - SimulationOnlyReset and SimulationOnlyTraining can be * used to speed up simulation run times, and must never * be used in real silicon. Some VIPs may have checks on * DRAM reset parameters that may need to be disabled when * using SimulationOnlyReset. */ uint16_t pmurevision; /* * Byte offset 0x02, CSR Addr 0x54001, Direction=Out * PMU firmware revision ID * After training is run, this address will contain the * revision ID of the firmware */ uint8_t pstate; /* * Byte offset 0x04, CSR Addr 0x54002, Direction=In * Must be set to the target pstate to be trained * 0x0 = pstate 0 * 0x1 = pstate 1 * 0x2 = pstate 2 * 0x3 = pstate 3 * All other encodings are reserved */ uint8_t pllbypassen; /* * Byte offset 0x05, CSR Addr 0x54002, Direction=In * Set according to whether target pstate uses PHY PLL * bypass * 0x0 = PHY PLL is enabled for target pstate * 0x1 = PHY PLL is bypassed for target pstate */ uint16_t dramfreq; /* * Byte offset 0x06, CSR Addr 0x54003, Direction=In * DDR data rate for the target pstate in units of MT/s. * For example enter 0x0640 for DDR1600. */ uint8_t dfifreqratio; /* * Byte offset 0x08, CSR Addr 0x54004, Direction=In * Frequency ratio betwen DfiCtlClk and SDRAM memclk. * 0x1 = 1:1 * 0x2 = 1:2 * 0x4 = 1:4 */ uint8_t bpznresval; /* * Byte offset 0x09, CSR Addr 0x54004, Direction=In * Overwrite the value of precision resistor connected to * Phy BP_ZN * 0x00 = Do not program. Use current CSR value. * 0xf0 = 240 Ohm * 0x78 = 120 Ohm * 0x28 = 40 Ohm * All other values are reserved. * It is recommended to set this to 0x00. */ uint8_t phyodtimpedance; /* * Byte offset 0x0a, CSR Addr 0x54005, Direction=In * Must be programmed to the termination impedance in ohms * used by PHY during reads. * * 0x0 = Firmware skips programming (must be manually * programmed by user prior to training start) * * See PHY databook for legal termination impedance values. * * For digital simulation, any legal value can be used. For * silicon, the users must determine the correct value * through SI simulation or other methods. */ uint8_t phydrvimpedance; /* * Byte offset 0x0b, CSR Addr 0x54005, Direction=In * Must be programmed to the driver impedance in ohms used * by PHY during writes for all DBYTE drivers * (DQ/DM/DBI/DQS). * * 0x0 = Firmware skips programming (must be manually * programmed by user prior to training start) * * See PHY databook for legal R_on driver impedance values. * * For digital simulation, any value can be used that is not * Hi-Z. For silicon, the users must determine the correct * value through SI simulation or other methods. */ uint8_t phyvref; /* * Byte offset 0x0c, CSR Addr 0x54006, Direction=In * Must be programmed with the Vref level to be used by the * PHY during reads * * The units of this field are a percentage of VDDQ * according to the following equation: * * Receiver Vref = VDDQ*phyvref[6:0]/128 * * For example to set Vref at 0.25*VDDQ, set this field to * 0x20. * * For digital simulation, any legal value can be used. For * silicon, the users must calculate the analytical Vref by * using the impedances, terminations, and series resistance * present in the system. */ uint8_t lp4misc; /* * Byte offset 0x0d, CSR Addr 0x54006, Direction=In * Lp4 specific options for training. * * Bit fields: * * lp4misc[0] Enable dfi_reset_n * * 0x0 = (Recommended) PHY internal registers control * memreset during training, and also after training. * dfi_reset_n cannot control the PHY BP_MEMRESET_L pin. * * 0x1 = Enables dfi_reset_n to control memreset after * training. PHY Internal registers control memreset * during training only. To ensure that no glitches occur * on BP_MEMRESET at the end of training, The MC must * drive dfi_reset_n=1'b1 _prior to starting training_ * * lp4misc[7-1] RFU, must be zero */ uint8_t reserved0e; /* * Byte offset 0x0e, CSR Addr 0x54007, Direction=In * Bit Field for enabling optional 2D training features * that impact both Rx2D and Tx2D. * * reserved0E[0:3]: bitTimeControl * input for the amount of data bits 2D writes/reads per DQ * before deciding if any specific voltage and delay setting * passes or fails. Every time this input increases by 1, * the number of 2D data comparisons is doubled. The 2D run * time will increase proportionally to the number of bit * times requested per point. * 0 = 288 bits per point (legacy behavior) * 1 = 576 bits per point * 2 = 1.125 kilobits per point * . . . * 15 = 9 megabits per point * * reserved0E[4]: Exhaustive2D * 0 = 2D optimization assumes the optimal trained point * is near the 1D trained point (legacy behavior) * 1 = 2D optimization searches the entire passing region * at the cost of run time. Recommended for optimal * results any time the optimal trained point is expected * to be near the edges of the eyes instead of near the 1D * trained point. * * reserved0E[5]: Detect Vref Eye Truncation, ignored if * eyeWeight2DControl == 0. * 0 = 2D optimizes for the passing region it can measure. * 1 = For every eye, 2D checks If the legal voltage range * truncated the eye. If the true voltage margin cannot be * measured, 2D will optimize heavily for delay margin * instead of using incomplete voltage margin data. Eyes * that are not truncated will still be optimized using * user programmed weights. * * reserved0E[6]: eyeWeight2DControl * 0 = Use 8 bit weights for Delay_Weight2D and * Voltage_Weight2D and disable TrunkV behavior. * 1 = Use 4 bit weights for Delay_weight2D and * Voltage_Weight2D and enable TrunkV behavior. * * reserved0E[7]: RFU, must be 0 */ uint8_t cstestfail; /* * Byte offset 0x0f, CSR Addr 0x54007, Direction=Out * This field will be set if training fails on any rank. * 0x0 = No failures * non-zero = one or more ranks failed training */ uint16_t sequencectrl; /* * Byte offset 0x10, CSR Addr 0x54008, Direction=In * Controls the training steps to be run. Each bit * corresponds to a training step. * * If the bit is set to 1, the training step will run. * If the bit is set to 0, the training step will be * skipped. * * Training step to bit mapping: * sequencectrl[0] = Run DevInit - Device/phy * initialization. Should always be set. * sequencectrl[1] = Run WrLvl - Write leveling * sequencectrl[2] = Run RxEn - Read gate training * sequencectrl[3] = Run RdDQS1D - 1d read dqs training * sequencectrl[4] = Run WrDQ1D - 1d write dq training * sequencectrl[5] = RFU, must be zero * sequencectrl[6] = RFU, must be zero * sequencectrl[7] = RFU, must be zero * sequencectrl[8] = Run RdDeskew - Per lane read dq deskew * training * sequencectrl[9] = Run MxRdLat - Max read latency training * sequencectrl[11-10] = RFU, must be zero * sequencectrl[12] = Run LPCA - CA Training * sequencectrl[15-13] = RFU, must be zero */ uint8_t hdtctrl; /* * Byte offset 0x12, CSR Addr 0x54009, Direction=In * To control the total number of debug messages, a * verbosity subfield (hdtctrl, Hardware Debug Trace * Control) exists in the message block. Every message has a * verbosity level associated with it, and as the hdtctrl * value is increased, less important s messages stop being * sent through the mailboxes. The meanings of several major * hdtctrl thresholds are explained below: * * 0x04 = Maximal debug messages (e.g., Eye contours) * 0x05 = Detailed debug messages (e.g. Eye delays) * 0x0A = Coarse debug messages (e.g. rank information) * 0xC8 = Stage completion * 0xC9 = Assertion messages * 0xFF = Firmware completion messages only */ uint8_t reserved13; /* * Byte offset 0x13, CSR Addr 0x54009, Direction=In * * 0 = Default operation, unchanged. * Others = RD DQ calibration Training steps are completed * with user specified pattern. */ uint8_t reserved14; /* * Byte offset 0x14, CSR Addr 0x5400a, Direction=In * Configure rd2D search iteration from a starting seed * point: * * reserved14[5:0]: If reserved14[6] is 0, Number of search * iterations (if 0, then default is 20); otherwise if this * value non zero, this value is used as a delta to filter * out points during the averaging: when averaging over a * dimension (delay or voltage), the points having a margin * smaller than the max of the eye in this dimension by at * least this delta value are filtered out. * * reserved14[6]: If set, instead of search, extract center * using an averaging function over the eye surface area, * where some points can be filtered out using * reserved14[5:0] * * reserved14[7]: if set, start search with large step size, * decreasing at each 4 iterations, down to 1 (do not care * if reserved14[6] is set) */ uint8_t reserved15; /* * Byte offset 0x15, CSR Addr 0x5400a, Direction=In * Configure wr2D search iteration from a starting seed * point: * * reserved15[5:0]: If reserved15[6] is 0, Number of search * iterations (if 0, then default is 20); otherwise if this * value non zero, this value is used as a delta to filter * out points during the averaging: when averaging over a * dimension (delay or voltage), the points having a margin * smaller than the max of the eye in this dimension by at * least this delta value are filtered out. * * reserved15[6]: If set, instead of search, extract center * using an averaging function over the eye surface area, * where some points can be filtered out using * reserved15[5:0] * * reserved15[7]: if set, start search with large step size, * decreasing at each 4 iterations, down to 1 (do not care * if reserved15[6] is set) */ uint8_t dfimrlmargin; /* * Byte offset 0x16, CSR Addr 0x5400b, Direction=In * Margin added to smallest passing trained DFI Max Read * Latency value, in units of DFI clocks. Recommended to be * >= 1. * * This margin must include the maximum positive drift * expected in tDQSCK over the target temperature and * voltage range of the users system. */ uint8_t reserved17; /* * Byte offset 0x17, CSR Addr 0x5400b, Direction=In * Configure DB from which extra info is dump during 2D * training when maximal debug is set: * * reserved17[3:0]: first DB * * reserved17[7:4]: number of DB, including first DB (if 0, * no extra debug per DB is dump) */ uint8_t usebroadcastmr; /* * Byte offset 0x18, CSR Addr 0x5400c, Direction=In * Training firmware can optionally set per rank mode * register values for DRAM partial array self-refresh * features if desired. * * 0x0 = Use mr<1:4, 11:14, 16:17, 22, 24>_a0 for rank 0 * channel A * Use mr<1:4, 11:14, 16:17, 22, 24>_b0 for rank 0 * channel B * Use mr<1:4, 11:14, 16:17, 22, 24>_a1 for rank 1 * channel A * Use mr<1:4, 11:14, 16:17, 22, 24>_b1 for rank 1 * channel B * * 0x1 = Use mr<1:4, 11:14, 16:17, 22, 24>_a0 setting for * all channels/ranks * * It is recommended in most LPDDR4 system configurations * to set this to 1. * It is recommended in LPDDR4x system configurations to * set this to 0. */ uint8_t lp4quickboot; /* * Byte offset 0x19, CSR Addr 0x5400c, Direction=In * Enable Quickboot. It must be set to 0x0 since Quickboot * is only supported in dedicated Quickboot firmware. */ uint8_t reserved1a; /* * Byte offset 0x1a, CSR Addr 0x5400d, Direction=In * Input for constraining the range of vref(DQ) values * training will collect data for, usually reducing training * time. However, too large of a voltage range may cause * longer 2D training times while too small of a voltage * range may truncate passing regions. When in doubt, leave * this field set to 0. * Used by 2D stages: Rd2D, Wr2D * * reserved1A[0-3]: Rd2D Voltage Range * 0 = Training will search all phy vref(DQ) settings * 1 = limit to +/-2 %VDDQ from phyVref * 2 = limit to +/-4 %VDDQ from phyVref * . . . * 15 = limit to +/-30% VDDQ from phyVref * * reserved1A[4-7]: Wr2D Voltage Range * 0 = Training will search all dram vref(DQ) settings * 1 = limit to +/-2 %VDDQ from mr14 * 2 = limit to +/-4 %VDDQ from mr14 * . . . * 15 = limit to +/-30% VDDQ from mr14 */ uint8_t catrainopt; /* * Byte offset 0x1b, CSR Addr 0x5400d, Direction=In * CA training option bit field * [0] CA VREF Training * 1 = Enable CA VREF Training * 0 = Disable CA VREF Training * WARNING: catrainopt[0] must be set to the same value in * 1D and 2D training. * * [1] Train terminated Rank only * 1 = Only train terminated rank in CA training * 0 = Train all ranks in CA training * * [2-7] RFU must be zero */ uint8_t x8mode; /* * Byte offset 0x1c, CSR Addr 0x5400e, Direction=In * X8 mode configuration: * 0x0 = x16 configuration for all devices * 0xF = x8 configuration for all devices * All other values are RFU */ uint8_t reserved1d; /* Byte offset 0x1d, CSR Addr 0x5400e, Direction=N/A */ uint8_t reserved1e; /* Byte offset 0x1e, CSR Addr 0x5400f, Direction=N/A */ uint8_t share2dvrefresult; /* * Byte offset 0x1f, CSR Addr 0x5400f, Direction=In * Bitmap that designates the phy's vref source for every * pstate * If share2dvrefresult[x] = 0, then after 2D training, * pstate x will continue using the phyVref provided in * pstate x's 1D messageblock. * If share2dvrefresult[x] = 1, then after 2D training, * pstate x will use the per-lane VrefDAC0/1 CSRs trained by * 2d training. */ uint8_t reserved20; /* Byte offset 0x20, CSR Addr 0x54010, Direction=N/A */ uint8_t reserved21; /* Byte offset 0x21, CSR Addr 0x54010, Direction=N/A */ uint16_t phyconfigoverride; /* * Byte offset 0x22, CSR Addr 0x54011, Direction=In * Override PhyConfig csr. * 0x0: Use hardware csr value for PhyConfing * (recommended) * Other values: Use value for PhyConfig instead of * Hardware value. * */ uint8_t enableddqscha; /* * Byte offset 0x24, CSR Addr 0x54012, Direction=In * Total number of DQ bits enabled in PHY Channel A */ uint8_t cspresentcha; /* * Byte offset 0x25, CSR Addr 0x54012, Direction=In * Indicates presence of DRAM at each chip select for PHY * channel A. * 0x1 = CS0 is populated with DRAM * 0x3 = CS0 and CS1 are populated with DRAM * * All other encodings are illegal */ int8_t cdd_cha_rr_1_0; /* * Byte offset 0x26, CSR Addr 0x54013, Direction=Out * This is a signed integer value. * Read to read critical delay difference from cs 1 to cs 0 * on Channel A. */ int8_t cdd_cha_rr_0_1; /* * Byte offset 0x27, CSR Addr 0x54013, Direction=Out * This is a signed integer value. * Read to read critical delay difference from cs 0 to cs 1 * on Channel A. */ int8_t cdd_cha_rw_1_1; /* * Byte offset 0x28, CSR Addr 0x54014, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 1 to cs 1 * on Channel A. */ int8_t cdd_cha_rw_1_0; /* * Byte offset 0x29, CSR Addr 0x54014, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 1 to cs 0 * on Channel A. */ int8_t cdd_cha_rw_0_1; /* * Byte offset 0x2a, CSR Addr 0x54015, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 0 to cs 1 * on Channel A. */ int8_t cdd_cha_rw_0_0; /* * Byte offset 0x2b, CSR Addr 0x54015, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs0 to cs 0 * on Channel A. */ int8_t cdd_cha_wr_1_1; /* * Byte offset 0x2c, CSR Addr 0x54016, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 1 to cs 1 * on Channel A. */ int8_t cdd_cha_wr_1_0; /* * Byte offset 0x2d, CSR Addr 0x54016, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 1 to cs 0 * on Channel A. */ int8_t cdd_cha_wr_0_1; /* * Byte offset 0x2e, CSR Addr 0x54017, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 0 to cs 1 * on Channel A. */ int8_t cdd_cha_wr_0_0; /* * Byte offset 0x2f, CSR Addr 0x54017, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 0 to cs 0 * on Channel A. */ int8_t cdd_cha_ww_1_0; /* * Byte offset 0x30, CSR Addr 0x54018, Direction=Out * This is a signed integer value. * Write to write critical delay difference from cs 1 to cs * 0 on Channel A. */ int8_t cdd_cha_ww_0_1; /* * Byte offset 0x31, CSR Addr 0x54018, Direction=Out * This is a signed integer value. * Write to write critical delay difference from cs 0 to cs * 1 on Channel A. */ uint8_t mr1_a0; /* * Byte offset 0x32, CSR Addr 0x54019, Direction=In * Value to be programmed in DRAM Mode Register 1 * {Channel A, Rank 0} */ uint8_t mr2_a0; /* * Byte offset 0x33, CSR Addr 0x54019, Direction=In * Value to be programmed in DRAM Mode Register 2 * {Channel A, Rank 0} */ uint8_t mr3_a0; /* * Byte offset 0x34, CSR Addr 0x5401a, Direction=In * Value to be programmed in DRAM Mode Register 3 * {Channel A, Rank 0} */ uint8_t mr4_a0; /* * Byte offset 0x35, CSR Addr 0x5401a, Direction=In * Value to be programmed in DRAM Mode Register 4 * {Channel A, Rank 0} */ uint8_t mr11_a0; /* * Byte offset 0x36, CSR Addr 0x5401b, Direction=In * Value to be programmed in DRAM Mode Register 11 * {Channel A, Rank 0} */ uint8_t mr12_a0; /* * Byte offset 0x37, CSR Addr 0x5401b, Direction=In * Value to be programmed in DRAM Mode Register 12 * {Channel A, Rank 0} */ uint8_t mr13_a0; /* * Byte offset 0x38, CSR Addr 0x5401c, Direction=In * Value to be programmed in DRAM Mode Register 13 * {Channel A, Rank 0} */ uint8_t mr14_a0; /* * Byte offset 0x39, CSR Addr 0x5401c, Direction=In * Value to be programmed in DRAM Mode Register 14 * {Channel A, Rank 0} */ uint8_t mr16_a0; /* * Byte offset 0x3a, CSR Addr 0x5401d, Direction=In * Value to be programmed in DRAM Mode Register 16 * {Channel A, Rank 0} */ uint8_t mr17_a0; /* * Byte offset 0x3b, CSR Addr 0x5401d, Direction=In * Value to be programmed in DRAM Mode Register 17 * {Channel A, Rank 0} */ uint8_t mr22_a0; /* * Byte offset 0x3c, CSR Addr 0x5401e, Direction=In * Value to be programmed in DRAM Mode Register 22 * {Channel A, Rank 0} */ uint8_t mr24_a0; /* * Byte offset 0x3d, CSR Addr 0x5401e, Direction=In * Value to be programmed in DRAM Mode Register 24 * {Channel A, Rank 0} */ uint8_t mr1_a1; /* * Byte offset 0x3e, CSR Addr 0x5401f, Direction=In * Value to be programmed in DRAM Mode Register 1 * {Channel A, Rank 1} */ uint8_t mr2_a1; /* * Byte offset 0x3f, CSR Addr 0x5401f, Direction=In * Value to be programmed in DRAM Mode Register 2 * {Channel A, Rank 1} */ uint8_t mr3_a1; /* * Byte offset 0x40, CSR Addr 0x54020, Direction=In * Value to be programmed in DRAM Mode Register 3 * {Channel A, Rank 1} */ uint8_t mr4_a1; /* * Byte offset 0x41, CSR Addr 0x54020, Direction=In * Value to be programmed in DRAM Mode Register 4 * {Channel A, Rank 1} */ uint8_t mr11_a1; /* * Byte offset 0x42, CSR Addr 0x54021, Direction=In * Value to be programmed in DRAM Mode Register 11 * {Channel A, Rank 1} */ uint8_t mr12_a1; /* * Byte offset 0x43, CSR Addr 0x54021, Direction=In * Value to be programmed in DRAM Mode Register 12 * {Channel A, Rank 1} */ uint8_t mr13_a1; /* * Byte offset 0x44, CSR Addr 0x54022, Direction=In * Value to be programmed in DRAM Mode Register 13 * {Channel A, Rank 1} */ uint8_t mr14_a1; /* * Byte offset 0x45, CSR Addr 0x54022, Direction=In * Value to be programmed in DRAM Mode Register 14 * {Channel A, Rank 1} */ uint8_t mr16_a1; /* * Byte offset 0x46, CSR Addr 0x54023, Direction=In * Value to be programmed in DRAM Mode Register 16 * {Channel A, Rank 1} */ uint8_t mr17_a1; /* * Byte offset 0x47, CSR Addr 0x54023, Direction=In * Value to be programmed in DRAM Mode Register 17 * {Channel A, Rank 1} */ uint8_t mr22_a1; /* * Byte offset 0x48, CSR Addr 0x54024, Direction=In * Value to be programmed in DRAM Mode Register 22 * {Channel A, Rank 1} */ uint8_t mr24_a1; /* * Byte offset 0x49, CSR Addr 0x54024, Direction=In * Value to be programmed in DRAM Mode Register 24 * {Channel A, Rank 1} */ uint8_t caterminatingrankcha; /* Byte offset 0x4a, CSR Addr 0x54025, Direction=In * Terminating Rank for CA bus on Channel A * 0x0 = Rank 0 is terminating rank * 0x1 = Rank 1 is terminating rank */ uint8_t reserved4b; /* Byte offset 0x4b, CSR Addr 0x54025, Direction=N/A */ uint8_t reserved4c; /* Byte offset 0x4c, CSR Addr 0x54026, Direction=N/A */ uint8_t reserved4d; /* Byte offset 0x4d, CSR Addr 0x54026, Direction=N/A */ uint8_t reserved4e; /* Byte offset 0x4e, CSR Addr 0x54027, Direction=N/A */ uint8_t reserved4f; /* Byte offset 0x4f, CSR Addr 0x54027, Direction=N/A */ uint8_t reserved50; /* Byte offset 0x50, CSR Addr 0x54028, Direction=N/A */ uint8_t reserved51; /* Byte offset 0x51, CSR Addr 0x54028, Direction=N/A */ uint8_t reserved52; /* Byte offset 0x52, CSR Addr 0x54029, Direction=N/A */ uint8_t reserved53; /* Byte offset 0x53, CSR Addr 0x54029, Direction=N/A */ uint8_t reserved54; /* Byte offset 0x54, CSR Addr 0x5402a, Direction=N/A */ uint8_t reserved55; /* Byte offset 0x55, CSR Addr 0x5402a, Direction=N/A */ uint8_t reserved56; /* Byte offset 0x56, CSR Addr 0x5402b, Direction=N/A */ uint8_t enableddqschb; /* * Byte offset 0x57, CSR Addr 0x5402b, Direction=In * Total number of DQ bits enabled in PHY Channel B */ uint8_t cspresentchb; /* * Byte offset 0x58, CSR Addr 0x5402c, Direction=In * Indicates presence of DRAM at each chip select for PHY * channel B. * 0x0 = No chip selects are populated with DRAM * 0x1 = CS0 is populated with DRAM * 0x3 = CS0 and CS1 are populated with DRAM * * All other encodings are illegal */ int8_t cdd_chb_rr_1_0; /* * Byte offset 0x59, CSR Addr 0x5402c, Direction=Out * This is a signed integer value. * Read to read critical delay difference from cs 1 to cs 0 * on Channel B. */ int8_t cdd_chb_rr_0_1; /* * Byte offset 0x5a, CSR Addr 0x5402d, Direction=Out * This is a signed integer value. * Read to read critical delay difference from cs 0 to cs 1 * on Channel B. */ int8_t cdd_chb_rw_1_1; /* * Byte offset 0x5b, CSR Addr 0x5402d, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 1 to cs 1 * on Channel B. */ int8_t cdd_chb_rw_1_0; /* * Byte offset 0x5c, CSR Addr 0x5402e, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 1 to cs 0 * on Channel B. */ int8_t cdd_chb_rw_0_1; /* * Byte offset 0x5d, CSR Addr 0x5402e, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs 0 to cs 1 * on Channel B. */ int8_t cdd_chb_rw_0_0; /* * Byte offset 0x5e, CSR Addr 0x5402f, Direction=Out * This is a signed integer value. * Read to write critical delay difference from cs01 to cs 0 * on Channel B. */ int8_t cdd_chb_wr_1_1; /* * Byte offset 0x5f, CSR Addr 0x5402f, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 1 to cs 1 * on Channel B. */ int8_t cdd_chb_wr_1_0; /* * Byte offset 0x60, CSR Addr 0x54030, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 1 to cs 0 * on Channel B. */ int8_t cdd_chb_wr_0_1; /* * Byte offset 0x61, CSR Addr 0x54030, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 0 to cs 1 * on Channel B. */ int8_t cdd_chb_wr_0_0; /* * Byte offset 0x62, CSR Addr 0x54031, Direction=Out * This is a signed integer value. * Write to read critical delay difference from cs 0 to cs 0 * on Channel B. */ int8_t cdd_chb_ww_1_0; /* * Byte offset 0x63, CSR Addr 0x54031, Direction=Out * This is a signed integer value. * Write to write critical delay difference from cs 1 to cs * 0 on Channel B. */ int8_t cdd_chb_ww_0_1; /* * Byte offset 0x64, CSR Addr 0x54032, Direction=Out * This is a signed integer value. * Write to write critical delay difference from cs 0 to cs * 1 on Channel B. */ uint8_t mr1_b0; /* * Byte offset 0x65, CSR Addr 0x54032, Direction=In * Value to be programmed in DRAM Mode Register 1 * {Channel B, Rank 0} */ uint8_t mr2_b0; /* * Byte offset 0x66, CSR Addr 0x54033, Direction=In * Value to be programmed in DRAM Mode Register 2 * {Channel B, Rank 0} */ uint8_t mr3_b0; /* * Byte offset 0x67, CSR Addr 0x54033, Direction=In * Value to be programmed in DRAM Mode Register 3 * {Channel B, Rank 0} */ uint8_t mr4_b0; /* * Byte offset 0x68, CSR Addr 0x54034, Direction=In * Value to be programmed in DRAM Mode Register 4 * {Channel B, Rank 0} */ uint8_t mr11_b0; /* * Byte offset 0x69, CSR Addr 0x54034, Direction=In * Value to be programmed in DRAM Mode Register 11 * {Channel B, Rank 0} */ uint8_t mr12_b0; /* * Byte offset 0x6a, CSR Addr 0x54035, Direction=In * Value to be programmed in DRAM Mode Register 12 * {Channel B, Rank 0} */ uint8_t mr13_b0; /* * Byte offset 0x6b, CSR Addr 0x54035, Direction=In * Value to be programmed in DRAM Mode Register 13 * {Channel B, Rank 0} */ uint8_t mr14_b0; /* * Byte offset 0x6c, CSR Addr 0x54036, Direction=In * Value to be programmed in DRAM Mode Register 14 * {Channel B, Rank 0} */ uint8_t mr16_b0; /* * Byte offset 0x6d, CSR Addr 0x54036, Direction=In * Value to be programmed in DRAM Mode Register 16 * {Channel B, Rank 0} */ uint8_t mr17_b0; /* * Byte offset 0x6e, CSR Addr 0x54037, Direction=In * Value to be programmed in DRAM Mode Register 17 * {Channel B, Rank 0} */ uint8_t mr22_b0; /* * Byte offset 0x6f, CSR Addr 0x54037, Direction=In * Value to be programmed in DRAM Mode Register 22 * {Channel B, Rank 0} */ uint8_t mr24_b0; /* * Byte offset 0x70, CSR Addr 0x54038, Direction=In * Value to be programmed in DRAM Mode Register 24 * {Channel B, Rank 0} */ uint8_t mr1_b1; /* * Byte offset 0x71, CSR Addr 0x54038, Direction=In * Value to be programmed in DRAM Mode Register 1 * {Channel B, Rank 1} */ uint8_t mr2_b1; /* * Byte offset 0x72, CSR Addr 0x54039, Direction=In * Value to be programmed in DRAM Mode Register 2 * {Channel B, Rank 1} */ uint8_t mr3_b1; /* * Byte offset 0x73, CSR Addr 0x54039, Direction=In * Value to be programmed in DRAM Mode Register 3 * {Channel B, Rank 1} */ uint8_t mr4_b1; /* * Byte offset 0x74, CSR Addr 0x5403a, Direction=In * Value to be programmed in DRAM Mode Register 4 * {Channel B, Rank 1} */ uint8_t mr11_b1; /* * Byte offset 0x75, CSR Addr 0x5403a, Direction=In * Value to be programmed in DRAM Mode Register 11 * {Channel B, Rank 1} */ uint8_t mr12_b1; /* * Byte offset 0x76, CSR Addr 0x5403b, Direction=In * Value to be programmed in DRAM Mode Register 12 * {Channel B, Rank 1} */ uint8_t mr13_b1; /* * Byte offset 0x77, CSR Addr 0x5403b, Direction=In * Value to be programmed in DRAM Mode Register 13 * {Channel B, Rank 1} */ uint8_t mr14_b1; /* * Byte offset 0x78, CSR Addr 0x5403c, Direction=In * Value to be programmed in DRAM Mode Register 14 * {Channel B, Rank 1} */ uint8_t mr16_b1; /* * Byte offset 0x79, CSR Addr 0x5403c, Direction=In * Value to be programmed in DRAM Mode Register 16 * {Channel B, Rank 1} */ uint8_t mr17_b1; /* * Byte offset 0x7a, CSR Addr 0x5403d, Direction=In * Value to be programmed in DRAM Mode Register 17 * {Channel B, Rank 1} */ uint8_t mr22_b1; /* * Byte offset 0x7b, CSR Addr 0x5403d, Direction=In * Value to be programmed in DRAM Mode Register 22 * {Channel B, Rank 1} */ uint8_t mr24_b1; /* * Byte offset 0x7c, CSR Addr 0x5403e, Direction=In * Value to be programmed in DRAM Mode Register 24 * {Channel B, Rank 1} */ uint8_t caterminatingrankchb; /* Byte offset 0x7d, CSR Addr 0x5403e, Direction=In * Terminating Rank for CA bus on Channel B * 0x0 = Rank 0 is terminating rank * 0x1 = Rank 1 is terminating rank */ uint8_t reserved7e; /* Byte offset 0x7e, CSR Addr 0x5403f, Direction=N/A */ uint8_t reserved7f; /* Byte offset 0x7f, CSR Addr 0x5403f, Direction=N/A */ uint8_t reserved80; /* Byte offset 0x80, CSR Addr 0x54040, Direction=N/A */ uint8_t reserved81; /* Byte offset 0x81, CSR Addr 0x54040, Direction=N/A */ uint8_t reserved82; /* Byte offset 0x82, CSR Addr 0x54041, Direction=N/A */ uint8_t reserved83; /* Byte offset 0x83, CSR Addr 0x54041, Direction=N/A */ uint8_t reserved84; /* Byte offset 0x84, CSR Addr 0x54042, Direction=N/A */ uint8_t reserved85; /* Byte offset 0x85, CSR Addr 0x54042, Direction=N/A */ uint8_t reserved86; /* Byte offset 0x86, CSR Addr 0x54043, Direction=N/A */ uint8_t reserved87; /* Byte offset 0x87, CSR Addr 0x54043, Direction=N/A */ uint8_t reserved88; /* Byte offset 0x88, CSR Addr 0x54044, Direction=N/A */ uint8_t reserved89; /* Byte offset 0x89, CSR Addr 0x54044, Direction=N/A */ } __packed __aligned(2); #endif /* MNPMUSRAMMSGBLOCK_LPDDR4_H */