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hekate/bootloader/sec/tsec.c
Kostas Missos 0b45a5a11a bpmp: Reduce freq to 589MHz
3 users had issues with 602MHz.
This will probably bring the SoC binning compatibility to 100%.

Additionally, make it easy to change default boost frequency.

The tiny loss in perf, will be mitigated in Nyx. (It's actually even faster)
2019-12-07 02:01:29 +02:00

288 lines
7.1 KiB
C

/*
* Copyright (c) 2018 naehrwert
* Copyright (c) 2018-2019 CTCaer
* Copyright (c) 2018 balika011
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope 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.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <string.h>
#include "../sec/tsec.h"
#include "../sec/tsec_t210.h"
#include "../sec/se_t210.h"
#include "../soc/bpmp.h"
#include "../soc/clock.h"
#include "../soc/kfuse.h"
#include "../soc/smmu.h"
#include "../soc/t210.h"
#include "../mem/heap.h"
#include "../mem/mc.h"
#include "../utils/util.h"
#include "../hos/hos.h"
// #include "../gfx/gfx.h"
static int _tsec_dma_wait_idle()
{
u32 timeout = get_tmr_ms() + 10000;
while (!(TSEC(TSEC_DMATRFCMD) & TSEC_DMATRFCMD_IDLE))
if (get_tmr_ms() > timeout)
return 0;
return 1;
}
static int _tsec_dma_pa_to_internal_100(int not_imem, int i_offset, int pa_offset)
{
u32 cmd;
if (not_imem)
cmd = TSEC_DMATRFCMD_SIZE_256B; // DMA 256 bytes
else
cmd = TSEC_DMATRFCMD_IMEM; // DMA IMEM (Instruction memmory)
TSEC(TSEC_DMATRFMOFFS) = i_offset;
TSEC(TSEC_DMATRFFBOFFS) = pa_offset;
TSEC(TSEC_DMATRFCMD) = cmd;
return _tsec_dma_wait_idle();
}
int tsec_query(u8 *tsec_keys, u8 kb, tsec_ctxt_t *tsec_ctxt)
{
int res = 0;
u8 *fwbuf = NULL;
u32 *pdir, *car, *fuse, *pmc, *flowctrl, *se, *mc, *iram, *evec;
u32 *pkg11_magic_off;
bpmp_mmu_disable();
bpmp_clk_rate_set(BPMP_CLK_NORMAL);
// Enable clocks.
clock_enable_host1x();
usleep(2);
clock_enable_tsec();
clock_enable_sor_safe();
clock_enable_sor0();
clock_enable_sor1();
clock_enable_kfuse();
kfuse_wait_ready();
// Configure Falcon.
TSEC(TSEC_DMACTL) = 0;
TSEC(TSEC_IRQMSET) =
TSEC_IRQMSET_EXT(0xFF) |
TSEC_IRQMSET_WDTMR |
TSEC_IRQMSET_HALT |
TSEC_IRQMSET_EXTERR |
TSEC_IRQMSET_SWGEN0 |
TSEC_IRQMSET_SWGEN1;
TSEC(TSEC_IRQDEST) =
TSEC_IRQDEST_EXT(0xFF) |
TSEC_IRQDEST_HALT |
TSEC_IRQDEST_EXTERR |
TSEC_IRQDEST_SWGEN0 |
TSEC_IRQDEST_SWGEN1;
TSEC(TSEC_ITFEN) = TSEC_ITFEN_CTXEN | TSEC_ITFEN_MTHDEN;
if (!_tsec_dma_wait_idle())
{
res = -1;
goto out;
}
// Load firmware or emulate memio environment for newer TSEC fw.
if (kb == KB_FIRMWARE_VERSION_620)
TSEC(TSEC_DMATRFBASE) = (u32)tsec_ctxt->fw >> 8;
else
{
fwbuf = (u8 *)malloc(0x4000);
u8 *fwbuf_aligned = (u8 *)ALIGN((u32)fwbuf, 0x100);
memcpy(fwbuf_aligned, tsec_ctxt->fw, tsec_ctxt->size);
TSEC(TSEC_DMATRFBASE) = (u32)fwbuf_aligned >> 8;
}
for (u32 addr = 0; addr < tsec_ctxt->size; addr += 0x100)
{
if (!_tsec_dma_pa_to_internal_100(false, addr, addr))
{
res = -2;
goto out_free;
}
}
if (kb == KB_FIRMWARE_VERSION_620)
{
// Init SMMU translation for TSEC.
pdir = smmu_init_for_tsec();
smmu_init(tsec_ctxt->secmon_base);
// Enable SMMU
if (!smmu_is_used())
smmu_enable();
// Clock reset controller.
car = page_alloc(1);
memcpy(car, (void *)CLOCK_BASE, 0x1000);
car[CLK_RST_CONTROLLER_CLK_SOURCE_TSEC / 4] = 2;
smmu_map(pdir, CLOCK_BASE, (u32)car, 1, _WRITABLE | _READABLE | _NONSECURE);
// Fuse driver.
fuse = page_alloc(1);
memcpy((void *)&fuse[0x800/4], (void *)FUSE_BASE, 0x400);
fuse[0x82C / 4] = 0;
fuse[0x9E0 / 4] = (1 << (kb + 2)) - 1;
fuse[0x9E4 / 4] = (1 << (kb + 2)) - 1;
smmu_map(pdir, (FUSE_BASE - 0x800), (u32)fuse, 1, _READABLE | _NONSECURE);
// Power management controller.
pmc = page_alloc(1);
smmu_map(pdir, RTC_BASE, (u32)pmc, 1, _READABLE | _NONSECURE);
// Flow control.
flowctrl = page_alloc(1);
smmu_map(pdir, FLOW_CTLR_BASE, (u32)flowctrl, 1, _WRITABLE | _NONSECURE);
// Security engine.
se = page_alloc(1);
memcpy(se, (void *)SE_BASE, 0x1000);
smmu_map(pdir, SE_BASE, (u32)se, 1, _READABLE | _WRITABLE | _NONSECURE);
// Memory controller.
mc = page_alloc(1);
memcpy(mc, (void *)MC_BASE, 0x1000);
mc[MC_IRAM_BOM / 4] = 0;
mc[MC_IRAM_TOM / 4] = 0x80000000;
smmu_map(pdir, MC_BASE, (u32)mc, 1, _READABLE | _NONSECURE);
// IRAM
iram = page_alloc(0x30);
memcpy(iram, tsec_ctxt->pkg1, 0x30000);
// PKG1.1 magic offset.
pkg11_magic_off = (u32 *)(iram + ((tsec_ctxt->pkg11_off + 0x20) / 4));
smmu_map(pdir, 0x40010000, (u32)iram, 0x30, _READABLE | _WRITABLE | _NONSECURE);
// Exception vectors
evec = page_alloc(1);
smmu_map(pdir, EXCP_VEC_BASE, (u32)evec, 1, _READABLE | _WRITABLE | _NONSECURE);
}
// Execute firmware.
HOST1X(HOST1X_CH0_SYNC_SYNCPT_160) = 0x34C2E1DA;
TSEC(TSEC_STATUS) = 0;
TSEC(TSEC_BOOTKEYVER) = 1; // HOS uses key version 1.
TSEC(TSEC_BOOTVEC) = 0;
TSEC(TSEC_CPUCTL) = TSEC_CPUCTL_STARTCPU;
if (kb == KB_FIRMWARE_VERSION_620)
{
u32 start = get_tmr_us();
u32 k = se[SE_KEYTABLE_DATA0_REG_OFFSET / 4];
u32 key[16] = {0};
u32 kidx = 0;
while (*pkg11_magic_off != HOS_PKG11_MAGIC)
{
smmu_flush_all();
if (k != se[SE_KEYTABLE_DATA0_REG_OFFSET / 4])
{
k = se[SE_KEYTABLE_DATA0_REG_OFFSET / 4];
key[kidx++] = k;
}
// Failsafe.
if ((u32)get_tmr_us() - start > 125000)
break;
}
if (kidx != 8)
{
res = -6;
smmu_deinit_for_tsec();
goto out_free;
}
// Give some extra time to make sure PKG1.1 is decrypted.
msleep(50);
memcpy(tsec_keys, &key, 0x20);
memcpy(tsec_ctxt->pkg1, iram, 0x30000);
smmu_deinit_for_tsec();
// for (int i = 0; i < kidx; i++)
// gfx_printf("key %08X\n", key[i]);
// gfx_printf("cpuctl (%08X) mbox (%08X)\n", TSEC(TSEC_CPUCTL), TSEC(TSEC_STATUS));
// u32 errst = MC(MC_ERR_STATUS);
// gfx_printf(" MC %08X %08X %08X\n", MC(MC_INTSTATUS), errst, MC(MC_ERR_ADR));
// gfx_printf(" type: %02X\n", errst >> 28);
// gfx_printf(" smmu: %02X\n", (errst >> 25) & 3);
// gfx_printf(" dir: %s\n", (errst >> 16) & 1 ? "W" : "R");
// gfx_printf(" cid: %02x\n", errst & 0xFF);
}
else
{
if (!_tsec_dma_wait_idle())
{
res = -3;
goto out_free;
}
u32 timeout = get_tmr_ms() + 2000;
while (!TSEC(TSEC_STATUS))
if (get_tmr_ms() > timeout)
{
res = -4;
goto out_free;
}
if (TSEC(TSEC_STATUS) != 0xB0B0B0B0)
{
res = -5;
goto out_free;
}
// Fetch result.
HOST1X(HOST1X_CH0_SYNC_SYNCPT_160) = 0;
u32 buf[4];
buf[0] = SOR1(SOR_NV_PDISP_SOR_DP_HDCP_BKSV_LSB);
buf[1] = SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_BKSV_LSB);
buf[2] = SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_CN_MSB);
buf[3] = SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_CN_LSB);
SOR1(SOR_NV_PDISP_SOR_DP_HDCP_BKSV_LSB) = 0;
SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_BKSV_LSB) = 0;
SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_CN_MSB) = 0;
SOR1(SOR_NV_PDISP_SOR_TMDS_HDCP_CN_LSB) = 0;
memcpy(tsec_keys, &buf, 0x10);
}
out_free:;
free(fwbuf);
out:;
// Disable clocks.
clock_disable_kfuse();
clock_disable_sor1();
clock_disable_sor0();
clock_disable_sor_safe();
clock_disable_tsec();
bpmp_mmu_enable();
bpmp_clk_rate_set(BPMP_CLK_DEFAULT_BOOST);
return res;
}