329 lines
9.3 KiB
C
329 lines
9.3 KiB
C
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/*
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* Copyright (C) 2009-2012 Apple Inc. All rights reserved.
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*
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* This document is the property of Apple Inc.
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* It is considered confidential and proprietary.
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*
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* This document may not be reproduced or transmitted in any form,
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* in whole or in part, without the express written permission of
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* Apple Inc.
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*/
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#include <debug.h>
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#include <drivers/amc/amc.h>
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#include <drivers/amc/amc_phy.h>
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#include <drivers/dram.h>
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#include <lib/libc.h>
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#include <platform/chipid.h>
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#include <sys.h>
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#include "amg.h"
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#define CA_PIVOTS_LIST_SIZE (7)
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#define DQ_PIVOTS_LIST_SIZE (5)
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static const int ca_pivot_ps[CA_PIVOTS_LIST_SIZE] = {-375, -250, -125, 0, 125, 250, 375};
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static const int dq_pivot_ps[DQ_PIVOTS_LIST_SIZE] = {-500, -250, 0, 250, 500};
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static struct amc_phy_calibration_data amg_calibration_data = {
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.bit_time_ps = 2500,
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.min_ca_window_width_ps = 250,
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.min_dq_window_width_ps = 250,
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.ca_pivot_step_size_ps = 125,
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.dq_pivot_step_size_ps = 250,
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.max_offset_setting = 63,
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.min_offset_factor = 12,
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.ca_pivots_list_size = CA_PIVOTS_LIST_SIZE,
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.ca_pivot_ps = (int *)ca_pivot_ps,
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.dq_pivots_list_size = DQ_PIVOTS_LIST_SIZE,
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.dq_pivot_ps = (int *)dq_pivot_ps,
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};
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void amc_phy_init(bool resume)
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{
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int i;
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// overwrite bit_time_ps if presented
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if (amc_phy_params.bit_time_ps)
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amg_calibration_data.bit_time_ps = amc_phy_params.bit_time_ps;
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for (i = 0; i < AMC_NUM_CHANNELS; i++) {
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int ch = AMG_INDEX_FOR_CHANNEL(i); // cope with hole in AMG address space
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rAMG_CORE_CONFIG(ch) = amc_phy_params.core_config;
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#if !SUPPORT_FPGA
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// PHY ZQ calibration
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rAMG_ZQ_CONF(ch) = 0x00ff0096; // <rdar://problem/8263127>
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rAMG_ZQ_CONTROL(ch) = 0x00000009; // <rdar://problem/7502673>
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rAMG_ZQ_CONTROL(ch) = 0x0000000b;
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// Not testing the error bit. This will never happen in normal operation,
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// and in fact _can't_ be set in H4P B0.
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while ((rAMG_ZQ_STATUS(ch) & 0x80) == 0) ;
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// Train master DLL
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rAMG_DLL_CONTROL(ch) = 0x00110001;
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rAMG_DLL_CONTROL(ch) = 0x00110005;
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while ((rAMG_DLL_STATUS(ch) & 1) != 1) ;
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// check for timeout
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if ((rAMG_DLL_STATUS(ch) & 0x4) != 0)
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for (;;) ;
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if (amc_phy_params.flags & FLAG_AMG_PARAM_CAL_STATIC) {
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// CA static offset programming; note it's too early to use
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// MRRs, so this relies on the SOC fusing.
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uint16_t fine_lock = (rAMG_DLL_STATUS(ch) >> 5) & 0x3ff;
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uint32_t fine_unit = (amg_calibration_data.bit_time_ps) / fine_lock;
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uint32_t addr_offset;
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uint32_t vendor_id = chipid_get_memory_manufacturer();
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switch (vendor_id) {
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case JEDEC_MANUF_ID_SAMSUNG:
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addr_offset = (110/fine_unit) | (1 << 6); /* -110ps */
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break;
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case JEDEC_MANUF_ID_ELPIDA:
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addr_offset = (50/fine_unit) | (1 << 6); /* -50ps */
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break;
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case JEDEC_MANUF_ID_HYNIX:
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addr_offset = 0; /* 0ps */
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break;
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default:
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addr_offset = 0;
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break;
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}
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rAMG_ADDR_OFFSET(ch) = addr_offset;
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} else if (resume) {
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amc_phy_calibration_restore_ca_offset(i);
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}
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rAMG_DLL_TIMER(ch) = 0x0003061a;
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// set frequency scaling parameters
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if (likely(!amc_phy_params.freq_scale))
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rAMG_FREQ_SCALE(ch) = 0x00e40688;
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else
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rAMG_FREQ_SCALE(ch) = amc_phy_params.freq_scale;
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#endif // !SUPPORT_FPGA
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rAMG_READ_LATENCY(ch) = amc_phy_params.read_latency; // [linked to AMC phyrdwrtim]
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rAMG_GATE_OFFSET(ch) = amc_phy_params.gate_offset;
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rAMG_INIT_CONTROL(ch) = 0x00000001;
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}
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}
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void amc_phy_scale_dll(int freqsel, int factor)
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{
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int i;
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// Make sure AMG was inited.
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// Assumptions: all supported channels are inited together,
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// and channel 0 is always used.
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if ((rAMG_INIT_CONTROL(0) & 1) == 0)
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return;
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// Scale the current lock value
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for (i = 0; i < AMC_NUM_CHANNELS; i++) {
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int ch = AMG_INDEX_FOR_CHANNEL(i);
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uint16_t new_lock;
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uint16_t fine_lock;
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// The fine_lock is 10 bits and coarse is 8. Since the override
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// is in coarse units, we do shifty math on the fine units.
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fine_lock = (rAMG_DLL_STATUS(ch) >> 5) & 0x3ff;
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if (factor == 1)
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new_lock = fine_lock >> 2;
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else if (factor == 8)
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new_lock = fine_lock << 1;
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else
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panic("amc_phy_scale_dll: unsupported DLL scale factor");
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if (new_lock > 0xff)
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new_lock = 0xff;
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rAMG_DLL_OVERRIDE(ch) = new_lock;
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rAMG_DLL_CONTROL(ch) = 0x00110004;
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while (!(rAMG_DLL_STATUS(ch) & 1)) ;
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}
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}
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bool amc_phy_rddq_cal()
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{
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uint32_t *dq_cal_data;
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bool result;
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uint8_t index, i;
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uint32_t device_width;
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uint8_t slot, ch;
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uint16_t fine_lock;
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uint32_t fine_unit;
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uint32_t offset;
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result = false;
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if (amc_phy_params.flags & FLAG_AMG_PARAM_CAL_STATIC) {
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dq_cal_data = malloc(AMC_NUM_CHANNELS * 2 * sizeof(uint32_t));
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if (chipid_get_memory_dqcal(dq_cal_data)) {
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index = 0;
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device_width = (amc_get_memory_device_info())->width;
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for (i = 0; i < AMC_NUM_CHANNELS; i++) {
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ch = AMG_INDEX_FOR_CHANNEL(i); // cope with hole in AMG address space
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fine_lock = (rAMG_DLL_STATUS(ch) >> 5) & 0x3ff;
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fine_unit = (amg_calibration_data.bit_time_ps) / fine_lock;
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// Loop across all bytes twice, first for read then for write,
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// which matches the order in which the data is given to us.
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for (slot = 0; slot < device_width * 2; slot++) {
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offset = (((dq_cal_data[index] & 0x8) << 3) |
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((((dq_cal_data[index] & 0x7) * 40) / fine_unit) & 0x3f));
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dq_cal_data[index] >>= 4;
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if (slot < device_width)
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rAMG_RD_OFFSET(ch, slot) = offset;
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else
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rAMG_WR_OFFSET(ch, (slot - device_width)) = offset;
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// Bump at end of "device_width" bytes of read and write
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if ((slot % device_width) == (device_width - 1))
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index++;
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}
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}
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result = true;
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}
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free(dq_cal_data);
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}
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return result;
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}
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void amc_phy_bypass_prep(int step)
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{
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// Make sure AMG was inited.
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// Assumptions: all supported channels are inited together,
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// and channel 0 is always used.
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if ((rAMG_INIT_CONTROL(0) & 1) == 0)
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return;
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// We need to be sure the DLL is in forced mode. Reload the
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// original full-speed lock result. <rdar://problem/7269959>
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// Note the 0 is the unused freqsel argument.
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amc_phy_scale_dll(0, 1);
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}
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void amc_phy_finalize()
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{
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int i;
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// Enable pulse-mode DLL training
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for (i = 0; i < AMC_NUM_CHANNELS; i++) {
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int ch = AMG_INDEX_FOR_CHANNEL(i); // cope with hole in AMG address space
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rAMG_DLL_FILTER(ch) = 0x0000002e;
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rAMG_DLL_CONTROL(ch) = 0x00110006;
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}
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}
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void amc_phy_enable_dqs_pulldown(bool enable)
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{
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}
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void amc_phy_reset_fifos()
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{
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}
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const struct amc_phy_calibration_data * amc_phy_get_calibration_data()
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{
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return &amg_calibration_data;
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}
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void amc_phy_calibration_init(uint32_t *fine_lock_ps)
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{
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uint8_t ch;
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uint16_t lock_result;
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const struct amc_memory_device_info *dev_info;
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ASSERT(fine_lock_ps != NULL);
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*fine_lock_ps = 0;
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dev_info = amc_get_memory_device_info();
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for (ch = 0; ch < AMC_NUM_CHANNELS; ch++) {
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rAMG_DLL_FILTER(AMG_INDEX_FOR_CHANNEL(ch)) = 0;
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lock_result = ((rAMG_DLL_STATUS(AMG_INDEX_FOR_CHANNEL(ch)) >> 5) & 0x3ff); // fine value
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rAMG_DLL_OVERRIDE(AMG_INDEX_FOR_CHANNEL(ch)) = lock_result / 4; // coarse value
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amc_phy_run_dll_update(ch);
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*fine_lock_ps += (amg_calibration_data.bit_time_ps) / (lock_result);
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// <rdar://problem/10996362> Modified guidance for AMG bit_sample field setting
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if (((dev_info->vendor_id == JEDEC_MANUF_ID_SAMSUNG) && (dev_info->density == JEDEC_DENSITY_2Gb) && (dev_info->rev_id == 0)) ||
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((dev_info->vendor_id == JEDEC_MANUF_ID_SAMSUNG) && (dev_info->density == JEDEC_DENSITY_4Gb) && (dev_info->rev_id == 1)) ||
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((dev_info->vendor_id == JEDEC_MANUF_ID_HYNIX) && (dev_info->density == JEDEC_DENSITY_1Gb)))
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rAMG_DQCAL_CONTROL(AMG_INDEX_FOR_CHANNEL(ch)) = 0x00001ffb;
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else
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rAMG_DQCAL_CONTROL(AMG_INDEX_FOR_CHANNEL(ch)) = 0x00003ffb;
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}
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*fine_lock_ps = *fine_lock_ps / AMC_NUM_CHANNELS;
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}
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void amc_phy_run_dll_update(uint8_t ch)
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{
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uint8_t ch_amg_idx = AMG_INDEX_FOR_CHANNEL(ch);
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rAMG_DLL_CONTROL(ch_amg_idx) = 0x00110000 | (1 << 2) | (0 << 0);
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while ((rAMG_DLL_STATUS(ch_amg_idx) & 1) == 0) ;
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}
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void amc_phy_set_addr_offset(uint8_t ch, uint8_t value)
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{
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rAMG_ADDR_OFFSET(AMG_INDEX_FOR_CHANNEL(ch)) = value;
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}
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void amc_phy_set_rd_offset(uint8_t ch, uint8_t byte, uint8_t value)
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{
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rAMG_RD_OFFSET(AMG_INDEX_FOR_CHANNEL(ch), byte) = value;
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}
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void amc_phy_set_wr_offset(uint8_t ch, uint8_t byte, uint8_t value)
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{
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rAMG_WR_OFFSET(AMG_INDEX_FOR_CHANNEL(ch), byte) = value;
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}
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void amc_phy_configure_dll_pulse_mode(uint8_t ch, bool enable)
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{
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if (!enable) {
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rAMG_DLL_FILTER(AMG_INDEX_FOR_CHANNEL(ch)) = 0x0000000a;
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}
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else {
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rAMG_DLL_FILTER(AMG_INDEX_FOR_CHANNEL(ch)) = 0x0000002e;
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rAMG_DLL_CONTROL(AMG_INDEX_FOR_CHANNEL(ch)) = 0x00110006;
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}
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}
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void amc_phy_run_dq_training(uint8_t ch)
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{
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uint8_t ch_amg_idx = AMG_INDEX_FOR_CHANNEL(ch);
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rAMG_DQCAL_CONTROL(ch_amg_idx) |= (1 << 14); // start
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while ((rAMG_DQCAL_STATUS(ch_amg_idx) & 1) == 0) ; // wait for 'Done' bit to set
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}
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uint32_t amc_phy_get_dq_training_status(uint8_t ch, uint8_t byte, uint8_t num_bytes)
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{
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uint8_t byte_result;
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uint32_t status;
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status = rAMG_DQCAL_STATUS(AMG_INDEX_FOR_CHANNEL(ch));
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// bits[MAX_BYTE-1:0] of the byte_result field are for pos DQS strobe,
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// and bits [2*MAX_BYTE-1:MAX_BYTE] for neg DQS strobe. Final result is
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// 'AND' of two, for specified byte
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byte_result = (status & (1 << (byte + 1)));
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byte_result = byte_result && (status & (1 << (byte + num_bytes + 1)));
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return byte_result;
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}
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void amc_phy_shift_dq_offset(int8_t *dq_offset, uint8_t num_bytes) {
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amc_dram_shift_dq_offset(dq_offset, num_bytes);
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}
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