blob: 2f31906d836af646d708fd3897eeef8acfb22d25 [file] [log] [blame]
/*
* Copyright (c) 2015-2017, ARM Limited and Contributors. All rights reserved.
* Copyright (c) 2019, NVIDIA Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <string.h>
#include <arch_helpers.h>
#include <common/bl_common.h>
#include <common/debug.h>
#include <lib/mmio.h>
#include <lib/utils.h>
#include <lib/xlat_tables/xlat_tables_v2.h>
#include <mce.h>
#include <memctrl.h>
#include <memctrl_v2.h>
#include <smmu.h>
#include <tegra_def.h>
#include <tegra_platform.h>
/* Video Memory base and size (live values) */
static uint64_t video_mem_base;
static uint64_t video_mem_size_mb;
/*
* The following platform setup functions are weakly defined. They
* provide typical implementations that will be overridden by a SoC.
*/
#pragma weak plat_memctrl_tzdram_setup
void plat_memctrl_tzdram_setup(uint64_t phys_base, uint64_t size_in_bytes)
{
; /* do nothing */
}
/*
* Init Memory controller during boot.
*/
void tegra_memctrl_setup(void)
{
uint32_t val;
const uint32_t *mc_streamid_override_regs;
uint32_t num_streamid_override_regs;
const mc_streamid_security_cfg_t *mc_streamid_sec_cfgs;
uint32_t num_streamid_sec_cfgs;
const tegra_mc_settings_t *plat_mc_settings = tegra_get_mc_settings();
uint32_t i;
INFO("Tegra Memory Controller (v2)\n");
/* Program the SMMU pagesize */
tegra_smmu_init();
/* Get the settings from the platform */
assert(plat_mc_settings != NULL);
mc_streamid_override_regs = plat_mc_settings->streamid_override_cfg;
num_streamid_override_regs = plat_mc_settings->num_streamid_override_cfgs;
mc_streamid_sec_cfgs = plat_mc_settings->streamid_security_cfg;
num_streamid_sec_cfgs = plat_mc_settings->num_streamid_security_cfgs;
/* Program all the Stream ID overrides */
for (i = 0; i < num_streamid_override_regs; i++)
tegra_mc_streamid_write_32(mc_streamid_override_regs[i],
MC_STREAM_ID_MAX);
/* Program the security config settings for all Stream IDs */
for (i = 0; i < num_streamid_sec_cfgs; i++) {
val = mc_streamid_sec_cfgs[i].override_enable << 16 |
mc_streamid_sec_cfgs[i].override_client_inputs << 8 |
mc_streamid_sec_cfgs[i].override_client_ns_flag << 0;
tegra_mc_streamid_write_32(mc_streamid_sec_cfgs[i].offset, val);
}
/*
* All requests at boot time, and certain requests during
* normal run time, are physically addressed and must bypass
* the SMMU. The client hub logic implements a hardware bypass
* path around the Translation Buffer Units (TBU). During
* boot-time, the SMMU_BYPASS_CTRL register (which defaults to
* TBU_BYPASS mode) will be used to steer all requests around
* the uninitialized TBUs. During normal operation, this register
* is locked into TBU_BYPASS_SID config, which routes requests
* with special StreamID 0x7f on the bypass path and all others
* through the selected TBU. This is done to disable SMMU Bypass
* mode, as it could be used to circumvent SMMU security checks.
*/
tegra_mc_write_32(MC_SMMU_BYPASS_CONFIG,
MC_SMMU_BYPASS_CONFIG_SETTINGS);
/*
* Re-configure MSS to allow ROC to deal with ordering of the
* Memory Controller traffic. This is needed as the Memory Controller
* boots with MSS having all control, but ROC provides a performance
* boost as compared to MSS.
*/
if (plat_mc_settings->reconfig_mss_clients != NULL) {
plat_mc_settings->reconfig_mss_clients();
}
/* Program overrides for MC transactions */
if (plat_mc_settings->set_txn_overrides != NULL) {
plat_mc_settings->set_txn_overrides();
}
}
/*
* Restore Memory Controller settings after "System Suspend"
*/
void tegra_memctrl_restore_settings(void)
{
const tegra_mc_settings_t *plat_mc_settings = tegra_get_mc_settings();
assert(plat_mc_settings != NULL);
/*
* Re-configure MSS to allow ROC to deal with ordering of the
* Memory Controller traffic. This is needed as the Memory Controller
* resets during System Suspend with MSS having all control, but ROC
* provides a performance boost as compared to MSS.
*/
if (plat_mc_settings->reconfig_mss_clients != NULL) {
plat_mc_settings->reconfig_mss_clients();
}
/* Program overrides for MC transactions */
if (plat_mc_settings->set_txn_overrides != NULL) {
plat_mc_settings->set_txn_overrides();
}
/* video memory carveout region */
if (video_mem_base != 0ULL) {
tegra_mc_write_32(MC_VIDEO_PROTECT_BASE_LO,
(uint32_t)video_mem_base);
tegra_mc_write_32(MC_VIDEO_PROTECT_BASE_HI,
(uint32_t)(video_mem_base >> 32));
tegra_mc_write_32(MC_VIDEO_PROTECT_SIZE_MB, video_mem_size_mb);
/*
* MCE propagates the VideoMem configuration values across the
* CCPLEX.
*/
mce_update_gsc_videomem();
}
}
/*
* Secure the BL31 DRAM aperture.
*
* phys_base = physical base of TZDRAM aperture
* size_in_bytes = size of aperture in bytes
*/
void tegra_memctrl_tzdram_setup(uint64_t phys_base, uint32_t size_in_bytes)
{
/*
* Perform platform specific steps.
*/
plat_memctrl_tzdram_setup(phys_base, size_in_bytes);
}
/*
* Secure the BL31 TZRAM aperture.
*
* phys_base = physical base of TZRAM aperture
* size_in_bytes = size of aperture in bytes
*/
void tegra_memctrl_tzram_setup(uint64_t phys_base, uint32_t size_in_bytes)
{
uint32_t index;
uint32_t total_128kb_blocks = size_in_bytes >> 17;
uint32_t residual_4kb_blocks = (size_in_bytes & (uint32_t)0x1FFFF) >> 12;
uint32_t val;
INFO("Configuring TrustZone SRAM Memory Carveout\n");
/*
* Reset the access configuration registers to restrict access
* to the TZRAM aperture
*/
for (index = MC_TZRAM_CLIENT_ACCESS0_CFG0;
index < ((uint32_t)MC_TZRAM_CARVEOUT_CFG + (uint32_t)MC_GSC_CONFIG_REGS_SIZE);
index += 4U) {
tegra_mc_write_32(index, 0);
}
/*
* Enable CPU access configuration registers to access the TZRAM aperture
*/
if (!tegra_chipid_is_t186()) {
val = tegra_mc_read_32(MC_TZRAM_CLIENT_ACCESS1_CFG0);
val |= TZRAM_ALLOW_MPCORER | TZRAM_ALLOW_MPCOREW;
tegra_mc_write_32(MC_TZRAM_CLIENT_ACCESS1_CFG0, val);
}
/*
* Set the TZRAM base. TZRAM base must be 4k aligned, at least.
*/
assert((phys_base & (uint64_t)0xFFF) == 0U);
tegra_mc_write_32(MC_TZRAM_BASE_LO, (uint32_t)phys_base);
tegra_mc_write_32(MC_TZRAM_BASE_HI,
(uint32_t)(phys_base >> 32) & MC_GSC_BASE_HI_MASK);
/*
* Set the TZRAM size
*
* total size = (number of 128KB blocks) + (number of remaining 4KB
* blocks)
*
*/
val = (residual_4kb_blocks << MC_GSC_SIZE_RANGE_4KB_SHIFT) |
total_128kb_blocks;
tegra_mc_write_32(MC_TZRAM_SIZE, val);
/*
* Lock the configuration settings by disabling TZ-only lock
* and locking the configuration against any future changes
* at all.
*/
val = tegra_mc_read_32(MC_TZRAM_CARVEOUT_CFG);
val &= (uint32_t)~MC_GSC_ENABLE_TZ_LOCK_BIT;
val |= MC_GSC_LOCK_CFG_SETTINGS_BIT;
if (!tegra_chipid_is_t186()) {
val |= MC_GSC_ENABLE_CPU_SECURE_BIT;
}
tegra_mc_write_32(MC_TZRAM_CARVEOUT_CFG, val);
/*
* MCE propagates the security configuration values across the
* CCPLEX.
*/
mce_update_gsc_tzram();
}
static void tegra_lock_videomem_nonoverlap(uint64_t phys_base,
uint64_t size_in_bytes)
{
uint32_t index;
uint64_t total_128kb_blocks = size_in_bytes >> 17;
uint64_t residual_4kb_blocks = (size_in_bytes & (uint32_t)0x1FFFF) >> 12;
uint64_t val;
/*
* Reset the access configuration registers to restrict access to
* old Videomem aperture
*/
for (index = MC_VIDEO_PROTECT_CLEAR_ACCESS_CFG0;
index < ((uint32_t)MC_VIDEO_PROTECT_CLEAR_ACCESS_CFG0 + (uint32_t)MC_GSC_CONFIG_REGS_SIZE);
index += 4U) {
tegra_mc_write_32(index, 0);
}
/*
* Set the base. It must be 4k aligned, at least.
*/
assert((phys_base & (uint64_t)0xFFF) == 0U);
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_BASE_LO, (uint32_t)phys_base);
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_BASE_HI,
(uint32_t)(phys_base >> 32) & (uint32_t)MC_GSC_BASE_HI_MASK);
/*
* Set the aperture size
*
* total size = (number of 128KB blocks) + (number of remaining 4KB
* blocks)
*
*/
val = (uint32_t)((residual_4kb_blocks << MC_GSC_SIZE_RANGE_4KB_SHIFT) |
total_128kb_blocks);
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_SIZE, (uint32_t)val);
/*
* Lock the configuration settings by enabling TZ-only lock and
* locking the configuration against any future changes from NS
* world.
*/
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_CFG,
(uint32_t)MC_GSC_ENABLE_TZ_LOCK_BIT);
/*
* MCE propagates the GSC configuration values across the
* CCPLEX.
*/
}
static void tegra_unlock_videomem_nonoverlap(void)
{
/* Clear the base */
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_BASE_LO, 0);
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_BASE_HI, 0);
/* Clear the size */
tegra_mc_write_32(MC_VIDEO_PROTECT_CLEAR_SIZE, 0);
}
static void tegra_clear_videomem(uintptr_t non_overlap_area_start,
unsigned long long non_overlap_area_size)
{
int ret;
/*
* Map the NS memory first, clean it and then unmap it.
*/
ret = mmap_add_dynamic_region(non_overlap_area_start, /* PA */
non_overlap_area_start, /* VA */
non_overlap_area_size, /* size */
MT_NS | MT_RW | MT_EXECUTE_NEVER); /* attrs */
assert(ret == 0);
zero_normalmem((void *)non_overlap_area_start, non_overlap_area_size);
flush_dcache_range(non_overlap_area_start, non_overlap_area_size);
(void)mmap_remove_dynamic_region(non_overlap_area_start,
non_overlap_area_size);
}
/*
* Program the Video Memory carveout region
*
* phys_base = physical base of aperture
* size_in_bytes = size of aperture in bytes
*/
void tegra_memctrl_videomem_setup(uint64_t phys_base, uint32_t size_in_bytes)
{
uintptr_t vmem_end_old = video_mem_base + (video_mem_size_mb << 20);
uintptr_t vmem_end_new = phys_base + size_in_bytes;
unsigned long long non_overlap_area_size;
/*
* Setup the Memory controller to restrict CPU accesses to the Video
* Memory region
*/
INFO("Configuring Video Memory Carveout\n");
/*
* Configure Memory Controller directly for the first time.
*/
if (video_mem_base == 0U)
goto done;
/*
* Lock the non overlapping memory being cleared so that other masters
* do not accidently write to it. The memory would be unlocked once
* the non overlapping region is cleared and the new memory
* settings take effect.
*/
tegra_lock_videomem_nonoverlap(video_mem_base,
video_mem_size_mb << 20);
/*
* Clear the old regions now being exposed. The following cases
* can occur -
*
* 1. clear whole old region (no overlap with new region)
* 2. clear old sub-region below new base
* 3. clear old sub-region above new end
*/
INFO("Cleaning previous Video Memory Carveout\n");
if ((phys_base > vmem_end_old) || (video_mem_base > vmem_end_new)) {
tegra_clear_videomem(video_mem_base,
video_mem_size_mb << 20U);
} else {
if (video_mem_base < phys_base) {
non_overlap_area_size = phys_base - video_mem_base;
tegra_clear_videomem(video_mem_base, non_overlap_area_size);
}
if (vmem_end_old > vmem_end_new) {
non_overlap_area_size = vmem_end_old - vmem_end_new;
tegra_clear_videomem(vmem_end_new, non_overlap_area_size);
}
}
done:
/* program the Videomem aperture */
tegra_mc_write_32(MC_VIDEO_PROTECT_BASE_LO, (uint32_t)phys_base);
tegra_mc_write_32(MC_VIDEO_PROTECT_BASE_HI,
(uint32_t)(phys_base >> 32));
tegra_mc_write_32(MC_VIDEO_PROTECT_SIZE_MB, size_in_bytes >> 20);
/* unlock the previous locked nonoverlapping aperture */
tegra_unlock_videomem_nonoverlap();
/* store new values */
video_mem_base = phys_base;
video_mem_size_mb = size_in_bytes >> 20;
/*
* MCE propagates the VideoMem configuration values across the
* CCPLEX.
*/
mce_update_gsc_videomem();
}
/*
* This feature exists only for v1 of the Tegra Memory Controller.
*/
void tegra_memctrl_disable_ahb_redirection(void)
{
; /* do nothing */
}
void tegra_memctrl_clear_pending_interrupts(void)
{
; /* do nothing */
}