/*
 * This file is part of the coreboot project.
 *
 * Copyright 2016 Google Inc.
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; version 2 of the License.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 */
#include <cbmem.h>
#include <console/console.h>
#include <fsp/util.h>
#include <memory_info.h>
#include <soc/intel/common/smbios.h>
#include <soc/meminit.h>
#include <stddef.h> /* required for FspmUpd.h */
#include <fsp/soc_binding.h>
#include <string.h>

static void set_lpddr4_defaults(FSP_M_CONFIG *cfg)
{
	/* Enable memory down BGA since it's the only LPDDR4 packaging. */
	cfg->Package = 1;
	cfg->MemoryDown = 1;

	cfg->ScramblerSupport = 1;
	cfg->ChannelHashMask = 0x36;
	cfg->SliceHashMask = 0x9;
	cfg->InterleavedMode = 2;
	cfg->ChannelsSlicesEnable = 0;
	cfg->MinRefRate2xEnable = 0;
	cfg->DualRankSupportEnable = 1;
	/* Don't enforce a memory size limit. */
	cfg->MemorySizeLimit = 0;
	/* Use a 2GiB I/O hole -- field is in MiB units. */
	cfg->LowMemoryMaxValue = 2 * (GiB/MiB);
	/* No restrictions on memory above 4GiB */
	cfg->HighMemoryMaxValue = 0;

	/* Always default to attempt to use saved training data. */
	cfg->DisableFastBoot = 0;

	/* LPDDR4 is memory down so no SPD addresses. */
	cfg->DIMM0SPDAddress = 0;
	cfg->DIMM1SPDAddress = 0;

	/* Clear all the rank enables. */
	cfg->Ch0_RankEnable = 0x0;
	cfg->Ch1_RankEnable = 0x0;
	cfg->Ch2_RankEnable = 0x0;
	cfg->Ch3_RankEnable = 0x0;

	/*
	 * Set the device width to x16 which is half a LPDDR4 module as that's
	 * what the reference code expects.
	 */
	cfg->Ch0_DeviceWidth = 0x1;
	cfg->Ch1_DeviceWidth = 0x1;
	cfg->Ch2_DeviceWidth = 0x1;
	cfg->Ch3_DeviceWidth = 0x1;

	/*
	 * Enable bank hashing (bit 1) and rank interleaving (bit 0) with
	 * a 1KiB address mapping (bits 5:4).
	 */
	cfg->Ch0_Option = 0x3;
	cfg->Ch1_Option = 0x3;
	cfg->Ch2_Option = 0x3;
	cfg->Ch3_Option = 0x3;

	/* Weak on-die termination. */
	cfg->Ch0_OdtConfig = 0;
	cfg->Ch1_OdtConfig = 0;
	cfg->Ch2_OdtConfig = 0;
	cfg->Ch3_OdtConfig = 0;
}

void meminit_lpddr4(FSP_M_CONFIG *cfg, int speed)
{
	uint8_t profile;

	switch (speed) {
	case LP4_SPEED_1600:
		profile = 0x9;
		break;
	case LP4_SPEED_2133:
		profile = 0xa;
		break;
	case LP4_SPEED_2400:
		profile = 0xb;
		break;
	default:
		printk(BIOS_WARNING, "Invalid LPDDR4 speed: %d\n", speed);
		/* Set defaults. */
		speed = LP4_SPEED_1600;
		profile = 0x9;
	}

	printk(BIOS_INFO, "LP4DDR speed is %dMHz\n", speed);
	cfg->Profile = profile;

	set_lpddr4_defaults(cfg);
}

static void enable_logical_chan0(FSP_M_CONFIG *cfg,
					int rank_density, int dual_rank,
					const struct lpddr4_swizzle_cfg *scfg)
{
	const struct lpddr4_chan_swizzle_cfg *chan;
	/* Number of bytes to copy per DQS. */
	const size_t sz = DQ_BITS_PER_DQS;
	int rank_mask;

	/*
	 * Logical channel 0 is comprised of physical channel 0 and 1.
	 * Physical channel 0 is comprised of the CH0_DQB signals.
	 * Physical channel 1 is comprised of the CH0_DQA signals.
	 */
	cfg->Ch0_DramDensity = rank_density;
	cfg->Ch1_DramDensity = rank_density;
	/* Enable ranks on both channels depending on dual rank option. */
	rank_mask = dual_rank ? 0x3 : 0x1;
	cfg->Ch0_RankEnable = rank_mask;
	cfg->Ch1_RankEnable = rank_mask;

	/*
	 * CH0_DQB byte lanes in the bit swizzle configuration field are
	 * not 1:1. The mapping within the swizzling field is:
	 *   indicies [0:7]   - byte lane 1 (DQS1) DQ[8:15]
	 *   indicies [8:15]  - byte lane 0 (DQS0) DQ[0:7]
	 *   indicies [16:23] - byte lane 3 (DQS3) DQ[24:31]
	 *   indicies [24:31] - byte lane 2 (DQS2) DQ[16:23]
	 */
	chan = &scfg->phys[LP4_PHYS_CH0B];
	memcpy(&cfg->Ch0_Bit_swizzling[0], &chan->dqs[LP4_DQS1], sz);
	memcpy(&cfg->Ch0_Bit_swizzling[8], &chan->dqs[LP4_DQS0], sz);
	memcpy(&cfg->Ch0_Bit_swizzling[16], &chan->dqs[LP4_DQS3], sz);
	memcpy(&cfg->Ch0_Bit_swizzling[24], &chan->dqs[LP4_DQS2], sz);

	/*
	 * CH0_DQA byte lanes in the bit swizzle configuration field are 1:1.
	 */
	chan = &scfg->phys[LP4_PHYS_CH0A];
	memcpy(&cfg->Ch1_Bit_swizzling[0], &chan->dqs[LP4_DQS0], sz);
	memcpy(&cfg->Ch1_Bit_swizzling[8], &chan->dqs[LP4_DQS1], sz);
	memcpy(&cfg->Ch1_Bit_swizzling[16], &chan->dqs[LP4_DQS2], sz);
	memcpy(&cfg->Ch1_Bit_swizzling[24], &chan->dqs[LP4_DQS3], sz);
}

static void enable_logical_chan1(FSP_M_CONFIG *cfg,
					int rank_density, int dual_rank,
					const struct lpddr4_swizzle_cfg *scfg)
{
	const struct lpddr4_chan_swizzle_cfg *chan;
	/* Number of bytes to copy per DQS. */
	const size_t sz = DQ_BITS_PER_DQS;
	int rank_mask;

	/*
	 * Logical channel 1 is comprised of physical channel 2 and 3.
	 * Physical channel 2 is comprised of the CH1_DQB signals.
	 * Physical channel 3 is comprised of the CH1_DQA signals.
	 */
	cfg->Ch2_DramDensity = rank_density;
	cfg->Ch3_DramDensity = rank_density;
	/* Enable ranks on both channels depending on dual rank option. */
	rank_mask = dual_rank ? 0x3 : 0x1;
	cfg->Ch2_RankEnable = rank_mask;
	cfg->Ch3_RankEnable = rank_mask;

	/*
	 * CH1_DQB byte lanes in the bit swizzle configuration field are
	 * not 1:1. The mapping within the swizzling field is:
	 *   indicies [0:7]   - byte lane 1 (DQS1) DQ[8:15]
	 *   indicies [8:15]  - byte lane 0 (DQS0) DQ[0:7]
	 *   indicies [16:23] - byte lane 3 (DQS3) DQ[24:31]
	 *   indicies [24:31] - byte lane 2 (DQS2) DQ[16:23]
	 */
	chan = &scfg->phys[LP4_PHYS_CH1B];
	memcpy(&cfg->Ch2_Bit_swizzling[0], &chan->dqs[LP4_DQS1], sz);
	memcpy(&cfg->Ch2_Bit_swizzling[8], &chan->dqs[LP4_DQS0], sz);
	memcpy(&cfg->Ch2_Bit_swizzling[16], &chan->dqs[LP4_DQS3], sz);
	memcpy(&cfg->Ch2_Bit_swizzling[24], &chan->dqs[LP4_DQS2], sz);

	/*
	 * CH1_DQA byte lanes in the bit swizzle configuration field are 1:1.
	 */
	chan = &scfg->phys[LP4_PHYS_CH1A];
	memcpy(&cfg->Ch3_Bit_swizzling[0], &chan->dqs[LP4_DQS0], sz);
	memcpy(&cfg->Ch3_Bit_swizzling[8], &chan->dqs[LP4_DQS1], sz);
	memcpy(&cfg->Ch3_Bit_swizzling[16], &chan->dqs[LP4_DQS2], sz);
	memcpy(&cfg->Ch3_Bit_swizzling[24], &chan->dqs[LP4_DQS3], sz);
}

void meminit_lpddr4_enable_channel(FSP_M_CONFIG *cfg, int logical_chan,
					int rank_density, int dual_rank,
					const struct lpddr4_swizzle_cfg *scfg)
{
	if (rank_density < LP4_8Gb_DENSITY ||
		rank_density > LP4_16Gb_DENSITY) {
		printk(BIOS_ERR, "Invalid LPDDR4 density: %d\n", rank_density);
		return;
	}

	switch (logical_chan) {
	case LP4_LCH0:
		enable_logical_chan0(cfg, rank_density, dual_rank, scfg);
		break;
	case LP4_LCH1:
		enable_logical_chan1(cfg, rank_density, dual_rank, scfg);
		break;
	default:
		printk(BIOS_ERR, "Invalid logical channel: %d\n", logical_chan);
		break;
	}
}

void meminit_lpddr4_by_sku(FSP_M_CONFIG *cfg,
				const struct lpddr4_cfg *lpcfg, size_t sku_id)
{
	const struct lpddr4_sku *sku;

	if (sku_id >= lpcfg->num_skus) {
		printk(BIOS_ERR, "Too few LPDDR4 SKUs: 0x%zx/0x%zx\n",
			sku_id, lpcfg->num_skus);
		return;
	}

	printk(BIOS_INFO, "LPDDR4 SKU id = 0x%zx\n", sku_id);

	sku = &lpcfg->skus[sku_id];

	meminit_lpddr4(cfg, sku->speed);

	if (sku->ch0_rank_density) {
		printk(BIOS_INFO, "LPDDR4 Ch0 density = %d\n",
			sku->ch0_rank_density);
		meminit_lpddr4_enable_channel(cfg, LP4_LCH0,
						sku->ch0_rank_density,
						sku->ch0_dual_rank,
						lpcfg->swizzle_config);
	}

	if (sku->ch1_rank_density) {
		printk(BIOS_INFO, "LPDDR4 Ch1 density = %d\n",
			sku->ch1_rank_density);
		meminit_lpddr4_enable_channel(cfg, LP4_LCH1,
						sku->ch1_rank_density,
						sku->ch1_dual_rank,
						lpcfg->swizzle_config);
	}

	cfg->PeriodicRetrainingDisable = sku->disable_periodic_retraining;
}

void save_lpddr4_dimm_info(const struct lpddr4_cfg *lp4cfg, size_t mem_sku)
{
	int channel, dimm, dimm_max, index;
	size_t hob_size;
	const DIMM_INFO *src_dimm;
	struct dimm_info *dest_dimm;
	struct memory_info *mem_info;
	const CHANNEL_INFO *channel_info;
	const FSP_SMBIOS_MEMORY_INFO *memory_info_hob;

	if (mem_sku >= lp4cfg->num_skus) {
		printk(BIOS_ERR, "Too few LPDDR4 SKUs: 0x%zx/0x%zx\n",
				mem_sku, lp4cfg->num_skus);
		return;
	}

	memory_info_hob = fsp_find_smbios_memory_info(&hob_size);

	/*
	 * Allocate CBMEM area for DIMM information used to populate SMBIOS
	 * table 17
	 */
	mem_info = cbmem_add(CBMEM_ID_MEMINFO, sizeof(*mem_info));
	if (mem_info == NULL) {
		printk(BIOS_ERR, "CBMEM entry for DIMM info missing\n");
		return;
	}
	memset(mem_info, 0, sizeof(*mem_info));

	/* Describe the first N DIMMs in the system */
	index = 0;
	dimm_max = ARRAY_SIZE(mem_info->dimm);
	for (channel = 0; channel < memory_info_hob->ChannelCount; channel++) {
		if (index >= dimm_max)
			break;
		channel_info = &memory_info_hob->ChannelInfo[channel];
		for (dimm = 0; dimm < channel_info->DimmCount; dimm++) {
			if (index >= dimm_max)
				break;
			src_dimm = &channel_info->DimmInfo[dimm];
			dest_dimm = &mem_info->dimm[index];

			if (!src_dimm->SizeInMb)
				continue;

			/* Populate the DIMM information */
			dimm_info_fill(dest_dimm,
				src_dimm->SizeInMb,
				memory_info_hob->MemoryType,
				memory_info_hob->MemoryFrequencyInMHz,
				channel_info->ChannelId,
				src_dimm->DimmId,
				lp4cfg->skus[mem_sku].part_num,
				strlen(lp4cfg->skus[mem_sku].part_num),
				memory_info_hob->DataWidth);
			index++;
		}
	}
	mem_info->dimm_cnt = index;
	printk(BIOS_DEBUG, "%d DIMMs found\n", mem_info->dimm_cnt);
}