tillitis-key/hw/application_fpga/fw/tk1/main.c

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/*
* Copyright (C) 2022 - Tillitis AB
* SPDX-License-Identifier: GPL-2.0-only
*/
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#include "../tk1_mem.h"
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#include "blake2s/blake2s.h"
#include "lib.h"
#include "proto.h"
#include "types.h"
// clang-format off
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static volatile uint32_t *uds = (volatile uint32_t *)TK1_MMIO_UDS_FIRST;
static volatile uint32_t *switch_app = (volatile uint32_t *)TK1_MMIO_TK1_SWITCH_APP;
static volatile uint32_t *name0 = (volatile uint32_t *)TK1_MMIO_TK1_NAME0;
static volatile uint32_t *name1 = (volatile uint32_t *)TK1_MMIO_TK1_NAME1;
static volatile uint32_t *ver = (volatile uint32_t *)TK1_MMIO_TK1_VERSION;
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static volatile uint32_t *udi = (volatile uint32_t *)TK1_MMIO_TK1_UDI_FIRST;
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static volatile uint32_t *cdi = (volatile uint32_t *)TK1_MMIO_TK1_CDI_FIRST;
static volatile uint32_t *app_addr = (volatile uint32_t *)TK1_MMIO_TK1_APP_ADDR;
static volatile uint32_t *app_size = (volatile uint32_t *)TK1_MMIO_TK1_APP_SIZE;
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static volatile uint8_t *fw_ram = (volatile uint8_t *)TK1_MMIO_FW_RAM_BASE;
static volatile uint32_t *led = (volatile uint32_t *)TK1_MMIO_TK1_LED;
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#define LED_RED (1 << TK1_MMIO_TK1_LED_R_BIT)
#define LED_GREEN (1 << TK1_MMIO_TK1_LED_G_BIT)
#define LED_BLUE (1 << TK1_MMIO_TK1_LED_B_BIT)
#define LED_WHITE (LED_RED | LED_GREEN | LED_BLUE)
// clang-format on
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struct namever {
char name0[4];
char name1[4];
uint32_t version;
};
static void print_hw_version(struct namever namever)
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{
puts("Hello, I'm ");
hexdump((uint8_t *)&namever.name0, 4);
putc(namever.name0[0]);
putc(namever.name0[1]);
putc(namever.name0[2]);
putc(namever.name0[3]);
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putc('-');
putc(namever.name1[0]);
putc(namever.name1[1]);
putc(namever.name1[2]);
putc(namever.name1[3]);
putc(':');
putinthex(namever.version);
lf();
}
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static struct namever get_hw_version(uint32_t name0, uint32_t name1,
uint32_t ver)
{
struct namever namever;
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hexdump((uint8_t *)&name0, 4);
putinthex(name0);
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lf();
namever.name0[0] = name0 >> 24;
namever.name0[1] = name0 >> 16;
namever.name0[2] = name0 >> 8;
namever.name0[3] = name0;
namever.name1[0] = name1 >> 24;
namever.name1[1] = name1 >> 16;
namever.name1[2] = name1 >> 8;
namever.name1[3] = name1;
namever.version = ver;
return namever;
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}
static void print_digest(uint8_t *md)
{
puts("The app digest:\n");
for (int j = 0; j < 4; j++) {
for (int i = 0; i < 8; i++) {
puthex(md[i + 8 * j]);
}
lf();
}
lf();
}
// CDI = blake2s(uds, blake2s(app), uss)
static void compute_cdi(uint8_t digest[32], uint8_t use_uss, uint8_t uss[32])
{
uint32_t local_cdi[8];
int len;
// To protect UDS we use a special firmware-only RAM for both
// the in parameter to blake2s and the blake2s context.
// Only word aligned access to UDS
wordcpy((void *)fw_ram, (void *)uds, 8);
memcpy((void *)fw_ram + 32, digest, 32);
if (use_uss != 0) {
memcpy((void *)fw_ram + 64, uss, 32);
len = 96;
} else {
len = 64;
}
blake2s_ctx *secure_ctx = (blake2s_ctx *)(fw_ram + len);
blake2s((void *)local_cdi, 32, NULL, 0, (const void *)fw_ram, len,
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secure_ctx);
// Write over the firmware-only RAM
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memset((void *)fw_ram, 0, TK1_MMIO_FW_RAM_SIZE);
// Only word aligned access to CDI
wordcpy((void *)cdi, (void *)local_cdi, 8);
}
void forever_redflash()
{
int led_on = 0;
for (;;) {
*led = led_on ? LED_RED : 0;
for (volatile int i = 0; i < 800000; i++) {
}
led_on = !led_on;
}
}
enum state {
FW_STATE_INITIAL,
FW_STATE_INIT_LOADING,
FW_STATE_LOADING,
FW_STATE_RUN
};
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int main()
{
struct namever namever = get_hw_version(*name0, *name1, *ver);
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struct frame_header hdr; // Used in both directions
uint8_t cmd[CMDLEN_MAXBYTES];
uint8_t rsp[CMDLEN_MAXBYTES];
uint8_t *loadaddr = (uint8_t *)TK1_APP_ADDR;
int left = 0; // Bytes left to receive
uint8_t use_uss = FALSE;
uint8_t uss[32] = {0};
uint8_t digest[32] = {0};
enum state state = FW_STATE_INITIAL;
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print_hw_version(namever);
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for (;;) {
switch (state) {
case FW_STATE_INITIAL:
break;
case FW_STATE_INIT_LOADING:
*app_addr = 0;
left = *app_size;
// Reset where to start loading the program
loadaddr = (uint8_t *)TK1_APP_ADDR;
break;
case FW_STATE_LOADING:
break;
case FW_STATE_RUN:
*app_addr = TK1_APP_ADDR;
// CDI = hash(uds, hash(app), uss)
compute_cdi(digest, use_uss, uss);
// Flip over to application mode
*switch_app = 1;
// Jump to app - doesn't return
// First clears memory of firmware remains
puts("Jumping to ");
putinthex(*app_addr);
lf();
// clang-format off
asm volatile(
// Clear the stack
"li a0, 0x40000000;" // TK1_RAM_BASE
"li a1, 0x40007000;" // TK1_APP_ADDR
"loop:;"
"sw zero, 0(a0);"
"addi a0, a0, 4;"
"blt a0, a1, loop;"
// Get value at TK1_MMIO_TK1_APP_ADDR
"lui a0,0xff000;"
"lw a0,0x030(a0);"
"jalr x0,0(a0);"
::: "memory");
// clang-format on
break; // This is never reached!
default:
puts("Unknown firmware state 0x");
puthex(state);
lf();
forever_redflash();
break; // Not reached
}
uint8_t in;
if (state == FW_STATE_LOADING) {
*led = LED_WHITE;
in = readbyte();
} else {
in = readbyte_ledflash(LED_WHITE, 800000);
}
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if (parseframe(in, &hdr) == -1) {
puts("Couldn't parse header\n");
continue;
}
memset(cmd, 0, CMDLEN_MAXBYTES);
// Now we know the size of the cmd frame, read it all
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read(cmd, hdr.len);
// Is it for us?
if (hdr.endpoint != DST_FW) {
puts("Message not meant for us\n");
continue;
}
// Reset response buffer
memset(rsp, 0, CMDLEN_MAXBYTES);
// Min length is 1 byte so this should always be here
switch (cmd[0]) {
case FW_CMD_NAME_VERSION:
puts("cmd: name-version\n");
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if (hdr.len != 1) {
// Bad length - give them an empty response
fwreply(hdr, FW_RSP_NAME_VERSION, rsp);
break;
}
memcpy(rsp, &namever.name0, 4);
memcpy(rsp + 4, &namever.name1, 4);
memcpy(rsp + 8, &namever.version, 4);
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fwreply(hdr, FW_RSP_NAME_VERSION, rsp);
// state unchanged
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break;
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case FW_CMD_GET_UDI:
puts("cmd: get-udi\n");
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if (hdr.len != 1) {
// Bad cmd length
rsp[0] = STATUS_BAD;
fwreply(hdr, FW_RSP_GET_UDI, rsp);
break;
}
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rsp[0] = STATUS_OK;
uint32_t udi_words[2];
wordcpy(udi_words, (void *)udi, 2);
memcpy(rsp + 1, udi_words, 2 * 4);
fwreply(hdr, FW_RSP_GET_UDI, rsp);
// state unchanged
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break;
case FW_CMD_LOAD_APP:
puts("cmd: load-app(size, uss)\n");
if (hdr.len != 128) {
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// Bad length
rsp[0] = STATUS_BAD;
fwreply(hdr, FW_RSP_LOAD_APP, rsp);
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break;
}
// cmd[1..4] contains the size.
uint32_t local_app_size = cmd[1] + (cmd[2] << 8) +
(cmd[3] << 16) +
(cmd[4] << 24);
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puts("app size: ");
putinthex(local_app_size);
lf();
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if (local_app_size == 0 ||
local_app_size > TK1_APP_MAX_SIZE) {
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rsp[0] = STATUS_BAD;
fwreply(hdr, FW_RSP_LOAD_APP, rsp);
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break;
}
*app_size = local_app_size;
// Do we have a USS at all?
if (cmd[5] != 0) {
// Yes
use_uss = TRUE;
memcpy(uss, cmd + 6, 32);
} else {
use_uss = FALSE;
}
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rsp[0] = STATUS_OK;
fwreply(hdr, FW_RSP_LOAD_APP, rsp);
state = FW_STATE_INIT_LOADING;
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break;
case FW_CMD_LOAD_APP_DATA:
puts("cmd: load-app-data\n");
if (hdr.len != 128 || (state != FW_STATE_INIT_LOADING &&
state != FW_STATE_LOADING)) {
// Bad cmd length or state
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rsp[0] = STATUS_BAD;
fwreply(hdr, FW_RSP_LOAD_APP_DATA, rsp);
break;
}
int nbytes;
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if (left > 127) {
nbytes = 127;
} else {
nbytes = left;
}
memcpy(loadaddr, cmd + 1, nbytes);
loadaddr += nbytes;
left -= nbytes;
if (left == 0) {
puts("Fully loaded ");
putinthex(*app_size);
lf();
// Compute Blake2S digest of the app, storing
// it for FW_STATE_RUN
blake2s_ctx ctx;
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blake2s(digest, 32, NULL, 0,
(const void *)TK1_APP_ADDR, *app_size,
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&ctx);
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print_digest(digest);
// And return the digest in final response
rsp[0] = STATUS_OK;
memcpy(&rsp[1], &digest, 32);
fwreply(hdr, FW_RSP_LOAD_APP_DATA_READY, rsp);
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state = FW_STATE_RUN;
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break;
}
rsp[0] = STATUS_OK;
fwreply(hdr, FW_RSP_LOAD_APP_DATA, rsp);
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state = FW_STATE_LOADING;
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break;
default:
puts("Got unknown firmware cmd: 0x");
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puthex(cmd[0]);
lf();
}
}
return (int)0xcafebabe;
}