/*
* Copyright (c) 2017, ARM Limited and Contributors. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <string.h>
#include <platform_def.h>
#include <arch_helpers.h>
#include <common/debug.h>
#include <drivers/console.h>
#include <drivers/delay_timer.h>
#include <lib/mmio.h>
#include <plat_private.h>
#include <soc.h>
#include "ddr_parameter.h"
/*
* The miniloader delivers the parameters about ddr usage info from address
* 0x02000000 and the data format is defined as below figure. It tells ATF the
* areas of ddr that are used by platform, we treat them as non-secure regions
* by default. Then we should parse the other part regions and configurate them
* as secure regions to avoid illegal access.
*
* [ddr usage info data format]
* 0x02000000
* -----------------------------------------------------------------------------
* | <name> | <size> | <description> |
* -----------------------------------------------------------------------------
* | count | 4byte | the array numbers of the |
* | | | 'addr_array' and 'size_array' |
* -----------------------------------------------------------------------------
* | reserved | 4byte | just for 'addr_array' 8byte aligned |
* -----------------------------------------------------------------------------
* | addr_array[count] | per 8byte | memory region base address |
* -----------------------------------------------------------------------------
* | size_array[count] | per 8byte | memory region size (byte) |
* -----------------------------------------------------------------------------
*/
/*
* function: read parameters info(ns-regions) and try to parse s-regions info
*
* @addr: head address to the ddr usage struct from miniloader
* @max_mb: the max ddr capacity(MB) that the platform support
*/
struct param_ddr_usage ddr_region_usage_parse(uint64_t addr, uint64_t max_mb)
{
uint64_t base, top;
uint32_t i, addr_offset, size_offset;
struct param_ddr_usage p;
memset(&p, 0, sizeof(p));
/* read how many blocks of ns-regions, read from offset: 0x0 */
p.ns_nr = mmio_read_32(addr + REGION_NR_OFFSET);
if ((p.ns_nr > DDR_REGION_NR_MAX) || (p.ns_nr == 0)) {
ERROR("over or zero region, nr=%d, max=%d\n",
p.ns_nr, DDR_REGION_NR_MAX);
return p;
}
/* whole ddr regions boundary, it will be used when parse s-regions */
p.boundary = max_mb;
/* calculate ns-region base addr and size offset */
addr_offset = REGION_ADDR_OFFSET;
size_offset = REGION_ADDR_OFFSET + p.ns_nr * REGION_DATA_PER_BYTES;
/* read all ns-regions base and top address */
for (i = 0; i < p.ns_nr; i++) {
base = mmio_read_64(addr + addr_offset);
top = base + mmio_read_64(addr + size_offset);
/*
* translate byte to MB and store info,
* Miniloader will promise every ns-region is MB aligned.
*/
p.ns_base[i] = RG_SIZE_MB(base);
p.ns_top[i] = RG_SIZE_MB(top);
addr_offset += REGION_DATA_PER_BYTES;
size_offset += REGION_DATA_PER_BYTES;
}
/*
* a s-region's base starts from previous ns-region's top, and a
* s-region's top ends with next ns-region's base. maybe like this:
*
* case1: ns-regison start from 0MB
* -----------------------------------------------
* | ns0 | S0 | ns1 | S1 | ns2 |
* 0----------------------------------------------- max_mb
*
*
* case2: ns-regison not start from 0MB
* -----------------------------------------------
* | S0 | ns0 | ns1 | ns2 | S1 |
* 0----------------------------------------------- max_mb
*/
/* like above case2 figure, ns-region is not start from 0MB */
if (p.ns_base[0] != 0) {
p.s_base[p.s_nr] = 0;
p.s_top[p.s_nr] = p.ns_base[0];
p.s_nr++;
}
/*
* notice: if ns-regions not start from 0MB, p.s_nr = 1 now, otherwise 0
*/
for (i = 0; i < p.ns_nr; i++) {
/*
* if current ns-regions top covers boundary,
* that means s-regions are all parsed yet, so finsh.
*/
if (p.ns_top[i] == p.boundary)
goto out;
/* s-region's base starts from previous ns-region's top */
p.s_base[p.s_nr] = p.ns_top[i];
/* s-region's top ends with next ns-region's base */
if (i + 1 < p.ns_nr)
p.s_top[p.s_nr] = p.ns_base[i + 1];
else
p.s_top[p.s_nr] = p.boundary;
p.s_nr++;
}
out:
return p;
}
