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gerrit.osmocom.org / simtrace2 / 4ba66d0098da894ffc91974bb633fad0707a7f5b / . / firmware / src_simtrace / card_emu.c
blob: ec9fdb8c19f8ef93800ebe181f62f1c19cf2885b [file] [log] [blame]
/* ISO7816-3 state machine for the card side */
/* (C) 2010-2015 by Harald Welte <hwelte@hmw-consulting.de>
*
* 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; either version 2 of the License, or
* (at your option) any later version.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include <assert.h>
#include <errno.h>
#include <string.h>
#include <stdint.h>
#include <sys/types.h>
#include "utils.h"
#include "trace.h"
#include "iso7816_fidi.h"
#include "tc_etu.h"
#include "card_emu.h"
#include "req_ctx.h"
#include "cardemu_prot.h"
#define NUM_SLOTS 2
#define ISO7816_3_INIT_WTIME 9600
#define ISO7816_3_DEFAULT_WI 10
#define ISO7816_3_ATR_LEN_MAX (1+32) /* TS plus 32 chars */
#define ISO7816_3_PB_NULL 0x60
enum iso7816_3_card_state {
ISO_S_WAIT_POWER, /* waiting for power being applied */
ISO_S_WAIT_CLK, /* waiting for clock being applied */
ISO_S_WAIT_RST, /* waiting for reset being released */
ISO_S_WAIT_ATR, /* waiting for start of ATR */
ISO_S_IN_ATR, /* transmitting ATR to reader */
ISO_S_IN_PTS, /* transmitting ATR to reader */
ISO_S_WAIT_TPDU, /* waiting for data from reader */
ISO_S_IN_TPDU, /* inside a TPDU */
};
/* detailed sub-states of ISO_S_IN_PTS */
enum pts_state {
PTS_S_WAIT_REQ_PTSS,
PTS_S_WAIT_REQ_PTS0,
PTS_S_WAIT_REQ_PTS1,
PTS_S_WAIT_REQ_PTS2,
PTS_S_WAIT_REQ_PTS3,
PTS_S_WAIT_REQ_PCK,
PTS_S_WAIT_RESP_PTSS = PTS_S_WAIT_REQ_PTSS | 0x10,
PTS_S_WAIT_RESP_PTS0 = PTS_S_WAIT_REQ_PTS0 | 0x10,
PTS_S_WAIT_RESP_PTS1 = PTS_S_WAIT_REQ_PTS1 | 0x10,
PTS_S_WAIT_RESP_PTS2 = PTS_S_WAIT_REQ_PTS2 | 0x10,
PTS_S_WAIT_RESP_PTS3 = PTS_S_WAIT_REQ_PTS3 | 0x10,
PTS_S_WAIT_RESP_PCK = PTS_S_WAIT_REQ_PCK | 0x10,
};
#define _PTSS 0
#define _PTS0 1
#define _PTS1 2
#define _PTS2 3
#define _PTS3 4
#define _PCK 5
/* T-PDU state machine states */
enum tpdu_state {
TPDU_S_WAIT_CLA, /* waiting for CLA byte from reader */
TPDU_S_WAIT_INS, /* waiting for INS byte from reader */
TPDU_S_WAIT_P1, /* waiting for P1 byte from reader */
TPDU_S_WAIT_P2, /* waiting for P2 byte from reader */
TPDU_S_WAIT_P3, /* waiting for P3 byte from reader */
TPDU_S_WAIT_PB, /* waiting for Tx of procedure byte */
TPDU_S_WAIT_RX, /* waiitng for more data from reader */
TPDU_S_WAIT_TX, /* waiting for more data to reader */
};
#define _CLA 0
#define _INS 1
#define _P1 2
#define _P2 3
#define _P3 4
struct card_handle {
enum iso7816_3_card_state state;
/* signal levels */
uint8_t vcc_active; /* 1 = on, 0 = off */
uint8_t in_reset; /* 1 = RST low, 0 = RST high */
uint8_t clocked; /* 1 = active, 0 = inactive */
/* timing parameters, from PTS */
uint8_t fi;
uint8_t di;
uint8_t wi;
uint8_t tc_chan; /* TC channel number */
uint8_t uart_chan; /* UART channel */
uint32_t waiting_time; /* in clocks */
/* ATR state machine */
struct {
uint8_t idx;
uint8_t len;
//uint8_t hist_len;
//uint8_t last_td;
uint8_t atr[ISO7816_3_ATR_LEN_MAX];
} atr;
/* PPS / PTS support */
struct {
enum pts_state state;
uint8_t req[6]; /* request bytes */
uint8_t resp[6]; /* response bytes */
} pts;
/* TPDU */
struct {
enum tpdu_state state;
uint8_t hdr[5]; /* CLA INS P1 P2 P3 */
} tpdu;
struct req_ctx *uart_rx_ctx; /* UART RX -> USB TX */
struct req_ctx *uart_tx_ctx; /* USB RX -> UART TX */
struct {
uint32_t tx_bytes;
uint32_t rx_bytes;
uint32_t pps;
} stats;
};
static void set_tpdu_state(struct card_handle *ch, enum tpdu_state new_ts);
static void set_pts_state(struct card_handle *ch, enum pts_state new_ptss);
static void flush_rx_buffer(struct card_handle *ch)
{
struct req_ctx *rctx;
struct cardemu_usb_msg_rx_data *rd;
rctx = ch->uart_rx_ctx;
if (!rctx)
return;
rd = (struct cardemu_usb_msg_rx_data *) ch->uart_rx_ctx->data;
/* store length of data payload fild in header */
rd->hdr.data_len = rctx->idx;
req_ctx_set_state(rctx, RCTX_S_USB_TX_PENDING);
ch->uart_rx_ctx = NULL;
/* FIXME: call into USB code to see if this buffer can
* be transmitted now */
}
/* convert a non-contiguous PTS request/responsei into a contiguous
* buffer, returning the number of bytes used in the buffer */
static int serialize_pts(uint8_t *out, const uint8_t *in)
{
int i = 0;
out[i++] = in[_PTSS];
out[i++] = in[_PTS0];
if (in[_PTS0] & (1 << 4))
out[i++] = in[_PTS1];
if (in[_PTS0] & (1 << 5))
out[i++] = in[_PTS2];
if (in[_PTS0] & (1 << 6))
out[i++] = in[_PTS3];
out[i++] = in[_PCK];
return i;
}
static void flush_pts(struct card_handle *ch)
{
struct req_ctx *rctx;
struct cardemu_usb_msg_pts_info *ptsi;
rctx = req_ctx_find_get(0, RCTX_S_FREE, RCTX_S_UART_RX_BUSY);
if (!rctx)
return;
ptsi = (struct cardemu_usb_msg_pts_info *) rctx->data;
ptsi->hdr.msg_type = CEMU_USB_MSGT_DO_PTS;
ptsi->hdr.data_len = serialize_pts(ptsi->req, ch->pts.req);
serialize_pts(ptsi->resp, ch->pts.resp);
req_ctx_set_state(rctx, RCTX_S_USB_TX_PENDING);
/* FIXME: call into USB code to see if this buffer can
* be transmitted now */
}
static void update_fidi(struct card_handle *ch)
{
int rc;
rc = compute_fidi_ratio(ch->fi, ch->di);
if (rc > 0 && rc < 0x400) {
TRACE_DEBUG("computed Fi(%u) Di(%u) ratio: %d\n",
ch->fi, ch->di, rc);
/* make sure UART uses new F/D ratio */
card_emu_uart_update_fidi(ch->uart_chan, rc);
/* notify ETU timer about this */
tc_etu_set_etu(ch->tc_chan, rc);
} else
TRACE_DEBUG("computed FiDi ration %d unsupported\n", rc);
}
/* Update the ISO 7816-3 TPDU receiver state */
static void card_set_state(struct card_handle *ch,
enum iso7816_3_card_state new_state)
{
switch (new_state) {
case ISO_S_WAIT_POWER:
case ISO_S_WAIT_CLK:
case ISO_S_WAIT_RST:
/* disable Rx and Tx of UART */
card_emu_uart_enable(ch->uart_chan, 0);
break;
case ISO_S_WAIT_ATR:
set_pts_state(ch, PTS_S_WAIT_REQ_PTSS);
/* Reset to initial Fi / Di ratio */
ch->fi = 1;
ch->di = 1;
update_fidi(ch);
/* initialize todefault WI, this will be overwritten if we
* receive TC2, and it will be programmed into hardware after
* ATR is finished */
ch->wi = ISO7816_3_DEFAULT_WI;
/* update waiting time to initial waiting time */
ch->waiting_time = ISO7816_3_INIT_WTIME;
tc_etu_set_wtime(ch->tc_chan, ch->waiting_time);
/* Set ATR sub-state to initial state */
ch->atr.idx = 0;
//set_atr_state(ch, ATR_S_WAIT_TS);
/* Notice that we are just coming out of reset */
//ch->sh.flags |= SIMTRACE_FLAG_ATR;
card_emu_uart_enable(ch->uart_chan, ENABLE_TX);
break;
break;
case ISO_S_WAIT_TPDU:
/* enable the receiver, disable transmitter */
set_tpdu_state(ch, TPDU_S_WAIT_CLA);
card_emu_uart_enable(ch->uart_chan, ENABLE_RX);
break;
case ISO_S_IN_ATR:
case ISO_S_IN_PTS:
case ISO_S_IN_TPDU:
/* do nothing */
break;
}
if (ch->state == new_state)
return;
TRACE_DEBUG("7816 card state %u -> %u\n", ch->state, new_state);
ch->state = new_state;
}
/**********************************************************************
* PTS / PPS handling
**********************************************************************/
/* Update the ATR sub-state */
static void set_pts_state(struct card_handle *ch, enum pts_state new_ptss)
{
TRACE_DEBUG("7816 PTS state %u -> %u\n", ch->pts.state, new_ptss);
ch->pts.state = new_ptss;
}
/* Determine the next PTS state */
static enum pts_state next_pts_state(struct card_handle *ch)
{
uint8_t is_resp = ch->pts.state & 0x10;
uint8_t sstate = ch->pts.state & 0x0f;
uint8_t *pts_ptr;
if (!is_resp)
pts_ptr = ch->pts.req;
else
pts_ptr = ch->pts.resp;
switch (sstate) {
case PTS_S_WAIT_REQ_PTSS:
goto from_ptss;
case PTS_S_WAIT_REQ_PTS0:
goto from_pts0;
case PTS_S_WAIT_REQ_PTS1:
goto from_pts1;
case PTS_S_WAIT_REQ_PTS2:
goto from_pts2;
case PTS_S_WAIT_REQ_PTS3:
goto from_pts3;
}
if (ch->pts.state == PTS_S_WAIT_REQ_PCK)
return PTS_S_WAIT_RESP_PTSS;
from_ptss:
return PTS_S_WAIT_REQ_PTS0 | is_resp;
from_pts0:
if (pts_ptr[_PTS0] & (1 << 4))
return PTS_S_WAIT_REQ_PTS1 | is_resp;
from_pts1:
if (pts_ptr[_PTS0] & (1 << 5))
return PTS_S_WAIT_REQ_PTS2 | is_resp;
from_pts2:
if (pts_ptr[_PTS0] & (1 << 6))
return PTS_S_WAIT_REQ_PTS3 | is_resp;
from_pts3:
return PTS_S_WAIT_REQ_PCK | is_resp;
}
static enum iso7816_3_card_state
process_byte_pts(struct card_handle *ch, uint8_t byte)
{
switch (ch->pts.state) {
case PTS_S_WAIT_REQ_PTSS:
ch->pts.req[_PTSS] = byte;
break;
case PTS_S_WAIT_REQ_PTS0:
ch->pts.req[_PTS0] = byte;
break;
case PTS_S_WAIT_REQ_PTS1:
ch->pts.req[_PTS1] = byte;
break;
case PTS_S_WAIT_REQ_PTS2:
ch->pts.req[_PTS2] = byte;
break;
case PTS_S_WAIT_REQ_PTS3:
ch->pts.req[_PTS3] = byte;
break;
case PTS_S_WAIT_REQ_PCK:
ch->pts.req[_PCK] = byte;
/* FIXME: check PCK */
/* FIXME: check if proposal matches capabilities in ATR */
memcpy(ch->pts.resp, ch->pts.req, sizeof(ch->pts.resp));
break;
default:
TRACE_DEBUG("process_byte_pts() in invalid state %u\n",
ch->pts.state);
break;
}
/* calculate the next state and set it */
set_pts_state(ch, next_pts_state(ch));
if (ch->pts.state == PTS_S_WAIT_RESP_PTSS) {
flush_pts(ch);
/* activate UART TX to transmit PTS response */
card_emu_uart_enable(ch->uart_chan, ENABLE_TX);
}
return ISO_S_IN_PTS;
}
/* return a single byte to be transmitted to the reader */
static int tx_byte_pts(struct card_handle *ch)
{
uint8_t byte;
/* 1: Determine the next transmit byte */
switch (ch->pts.state) {
case PTS_S_WAIT_RESP_PTSS:
byte = ch->pts.resp[_PTSS];
break;
case PTS_S_WAIT_RESP_PTS0:
byte = ch->pts.resp[_PTS0];
break;
case PTS_S_WAIT_RESP_PTS1:
byte = ch->pts.resp[_PTS1];
/* This must be TA1 */
ch->fi = byte >> 4;
ch->di = byte & 0xf;
TRACE_DEBUG("found Fi=%u Di=%u\n", ch->fi, ch->di);
break;
case PTS_S_WAIT_RESP_PTS2:
byte = ch->pts.resp[_PTS2];
break;
case PTS_S_WAIT_RESP_PTS3:
byte = ch->pts.resp[_PTS3];
break;
case PTS_S_WAIT_RESP_PCK:
byte = ch->pts.resp[_PCK];
/* update baud rate generator with Fi/Di */
update_fidi(ch);
break;
default:
TRACE_DEBUG("get_byte_pts() in invalid state %u\n",
ch->pts.state);
return 0;
}
/* 2: Transmit the byte */
card_emu_uart_tx(ch->uart_chan, byte);
/* 3: Update the state */
switch (ch->pts.state) {
case PTS_S_WAIT_RESP_PCK:
/* Wait for the next TPDU */
card_set_state(ch, ISO_S_WAIT_TPDU);
set_pts_state(ch, PTS_S_WAIT_REQ_PTSS);
break;
default:
/* calculate the next state and set it */
set_pts_state(ch, next_pts_state(ch));
break;
}
/* return number of bytes transmitted */
return 1;
}
/**********************************************************************
* TPDU handling
**********************************************************************/
/* compute number of data bytes according to Chapter 10.3.2 of 7816-3 */
static unsigned int t0_num_data_bytes(uint8_t p3, int reader_to_card)
{
if (reader_to_card) {
return p3;
} else {
if (p3 == 0)
return 256;
else
return p3;
}
}
/* add a just-received TPDU byte (from reader) to USB buffer */
static void add_tpdu_byte(struct card_handle *ch, uint8_t byte)
{
struct req_ctx *rctx;
struct cardemu_usb_msg_rx_data *rd;
unsigned int num_data_bytes = t0_num_data_bytes(ch->tpdu.hdr[_P3], 0);
/* ensure we have a buffer */
if (!ch->uart_rx_ctx) {
rctx = ch->uart_rx_ctx = req_ctx_find_get(0, RCTX_S_FREE, RCTX_S_UART_RX_BUSY);
if (!ch->uart_rx_ctx) {
TRACE_DEBUG("Received UART byte but unable to allocate Rx Buf\n");
return;
}
rd = (struct cardemu_usb_msg_rx_data *) ch->uart_rx_ctx->data;
cardemu_hdr_set(&rd->hdr, CEMU_USB_MSGT_DO_RX_DATA);
rctx->tot_len = sizeof(*rd);
rctx->idx = 0;
} else
rctx = ch->uart_rx_ctx;
rd = (struct cardemu_usb_msg_rx_data *) rctx->data;
rd->data[rctx->idx++] = byte;
rctx->tot_len++;
/* check if the buffer is full. If so, send it */
if (rctx->tot_len >= sizeof(*rd) + num_data_bytes) {
rd->flags |= CEMU_DATA_F_FINAL;
flush_rx_buffer(ch);
/* We need to transmit the SW now, */
set_tpdu_state(ch, TPDU_S_WAIT_TX);
} else if (rctx->tot_len >= rctx->size)
flush_rx_buffer(ch);
}
static void set_tpdu_state(struct card_handle *ch, enum tpdu_state new_ts)
{
if (ch->tpdu.state == new_ts)
return;
TRACE_DEBUG("7816 TPDU state %u -> %u\n", ch->tpdu.state, new_ts);
switch (new_ts) {
case TPDU_S_WAIT_CLA:
case TPDU_S_WAIT_RX:
card_emu_uart_enable(ch->uart_chan, ENABLE_RX);
break;
case TPDU_S_WAIT_PB:
/* we just completed the TPDU header from reader to card
* and now need to disable the receiver, enable the
* transmitter and transmit the procedure byte */
card_emu_uart_enable(ch->uart_chan, ENABLE_TX);
break;
}
ch->tpdu.state = new_ts;
}
static enum tpdu_state next_tpdu_state(struct card_handle *ch)
{
switch (ch->tpdu.state) {
case TPDU_S_WAIT_CLA:
return TPDU_S_WAIT_INS;
case TPDU_S_WAIT_INS:
return TPDU_S_WAIT_P1;
case TPDU_S_WAIT_P1:
return TPDU_S_WAIT_P2;
case TPDU_S_WAIT_P2:
return TPDU_S_WAIT_P3;
case TPDU_S_WAIT_P3:
return TPDU_S_WAIT_PB;
/* simply stay in Rx or Tx by default */
case TPDU_S_WAIT_PB:
return TPDU_S_WAIT_PB;
case TPDU_S_WAIT_RX:
return TPDU_S_WAIT_RX;
case TPDU_S_WAIT_TX:
return TPDU_S_WAIT_TX;
}
/* we should never reach here */
assert(0);
return -1;
}
static void send_tpdu_header(struct card_handle *ch)
{
struct req_ctx *rctx;
struct cardemu_usb_msg_rx_data *rd;
/* if we already/still have a context, send it off */
if (ch->uart_rx_ctx && ch->uart_rx_ctx->idx) {
flush_rx_buffer(ch);
}
/* ensure we have a new buffer */
ch->uart_rx_ctx = req_ctx_find_get(0, RCTX_S_FREE, RCTX_S_UART_RX_BUSY);
if (!ch->uart_rx_ctx)
return;
rctx = ch->uart_rx_ctx;
rd = (struct cardemu_usb_msg_rx_data *) rctx->data;
/* initializ header */
cardemu_hdr_set(&rd->hdr, CEMU_USB_MSGT_DO_RX_DATA);
rd->flags = CEMU_DATA_F_TPDU_HDR;
rctx->tot_len = sizeof(*rd) + sizeof(ch->tpdu.hdr);
rctx->idx = sizeof(ch->tpdu.hdr);
/* copy TPDU header to data field */
memcpy(rd->data, ch->tpdu.hdr, sizeof(ch->tpdu.hdr));
/* rd->data_len is set in flush_rx_buffer() */
flush_rx_buffer(ch);
}
static enum iso7816_3_card_state
process_byte_tpdu(struct card_handle *ch, uint8_t byte)
{
switch (ch->tpdu.state) {
case TPDU_S_WAIT_CLA:
ch->tpdu.hdr[_CLA] = byte;
set_tpdu_state(ch, next_tpdu_state(ch));
break;
case TPDU_S_WAIT_INS:
ch->tpdu.hdr[_INS] = byte;
set_tpdu_state(ch, next_tpdu_state(ch));
break;
case TPDU_S_WAIT_P1:
ch->tpdu.hdr[_P1] = byte;
set_tpdu_state(ch, next_tpdu_state(ch));
break;
case TPDU_S_WAIT_P2:
ch->tpdu.hdr[_P2] = byte;
set_tpdu_state(ch, next_tpdu_state(ch));
break;
case TPDU_S_WAIT_P3:
ch->tpdu.hdr[_P3] = byte;
set_tpdu_state(ch, next_tpdu_state(ch));
/* FIXME: start timer to transmit further 0x60 */
/* send the TPDU header as part of a procedure byte
* request to the USB host */
send_tpdu_header(ch);
break;
case TPDU_S_WAIT_RX:
add_tpdu_byte(ch, byte);
break;
default:
TRACE_DEBUG("process_byte_tpdu() in invalid state %u\n",
ch->tpdu.state);
}
/* ensure we stay in TPDU ISO state */
return ISO_S_IN_TPDU;
}
/* tx a single byte to be transmitted to the reader */
static int tx_byte_tpdu(struct card_handle *ch)
{
struct req_ctx *rctx;
struct cardemu_usb_msg_tx_data *td;
uint8_t byte;
/* ensure we are aware of any data that might be pending for
* transmit */
if (!ch->uart_tx_ctx) {
ch->uart_tx_ctx = req_ctx_find_get(0, RCTX_S_UART_TX_PENDING,
RCTX_S_UART_TX_BUSY);
if (!ch->uart_tx_ctx)
return 0;
/* start with index zero */
ch->uart_tx_ctx->idx = 0;
}
rctx = ch->uart_tx_ctx;
td = (struct cardemu_usb_msg_tx_data *) rctx->data;
/* take the next pending byte out of the rctx */
byte = td->data[rctx->idx++];
card_emu_uart_tx(ch->uart_chan, byte);
/* this must happen _after_ the byte has been transmittd */
switch (ch->tpdu.state) {
case TPDU_S_WAIT_PB:
/* if we just transmitted the procedure byte, we need to decide
* if we want to continue to receive or transmit */
if (td->flags & CEMU_DATA_F_PB_AND_TX)
set_tpdu_state(ch, TPDU_S_WAIT_TX);
else if (td->flags & CEMU_DATA_F_PB_AND_RX)
set_tpdu_state(ch, TPDU_S_WAIT_RX);
break;
}
/* check if the buffer has now been fully transmitted */
if ((rctx->idx >= td->hdr.data_len) ||
(td->data + rctx->idx >= rctx->data + rctx->tot_len)) {
if (td->flags & CEMU_DATA_F_PB_AND_RX) {
/* we have just sent the procedure byte and now
* need to continue receiving */
set_tpdu_state(ch, TPDU_S_WAIT_RX);
} else {
/* we have transmitted all bytes */
if (td->flags & CEMU_DATA_F_FINAL) {
/* this was the final part of the APDU, go
* back to state one*/
card_set_state(ch, ISO_S_WAIT_TPDU);
} else {
/* FIXME: call into USB code to chec if we need
* to submit a free buffer to accept
* further data on bulk out endpoint */
}
}
req_ctx_set_state(rctx, RCTX_S_FREE);
ch->uart_tx_ctx = NULL;
}
return 1;
}
/**********************************************************************
* Public API
**********************************************************************/
/* process a single byte received from the reader */
void card_emu_process_rx_byte(struct card_handle *ch, uint8_t byte)
{
int new_state = -1;
ch->stats.rx_bytes++;
switch (ch->state) {
case ISO_S_WAIT_POWER:
case ISO_S_WAIT_CLK:
case ISO_S_WAIT_RST:
case ISO_S_WAIT_ATR:
TRACE_DEBUG("Received UART char in 7816 state %u\n",
ch->state);
/* we shouldn't receive any data from the reader yet! */
break;
case ISO_S_WAIT_TPDU:
if (byte == 0xff) {
new_state = process_byte_pts(ch, byte);
ch->stats.pps++;
goto out_silent;
}
/* fall-through */
case ISO_S_IN_TPDU:
new_state = process_byte_tpdu(ch, byte);
break;
case ISO_S_IN_PTS:
new_state = process_byte_pts(ch, byte);
goto out_silent;
}
out_silent:
if (new_state != -1)
card_set_state(ch, new_state);
}
/* transmit a single byte to the reader */
int card_emu_tx_byte(struct card_handle *ch)
{
int rc = 0;
switch (ch->state) {
case ISO_S_IN_ATR:
if (ch->atr.idx < ch->atr.len) {
uint8_t byte;
byte = ch->atr.atr[ch->atr.idx++];
rc = 1;
card_emu_uart_tx(ch->uart_chan, byte);
/* detect end of ATR */
if (ch->atr.idx >= ch->atr.len)
card_set_state(ch, ISO_S_WAIT_TPDU);
}
break;
case ISO_S_IN_PTS:
rc = tx_byte_pts(ch);
break;
case ISO_S_IN_TPDU:
rc = tx_byte_tpdu(ch);
break;
}
if (rc)
ch->stats.tx_bytes++;
/* if we return 0 here, the UART needs to disable transmit-ready
* interrupts */
return rc;
}
/* hardware driver informs us that a card I/O signal has changed */
void card_emu_io_statechg(struct card_handle *ch, enum card_io io, int active)
{
switch (io) {
case CARD_IO_VCC:
if (active == 0) {
tc_etu_disable(ch->tc_chan);
card_set_state(ch, ISO_S_WAIT_POWER);
} else if (active == 1 && ch->vcc_active == 0)
card_set_state(ch, ISO_S_WAIT_CLK);
ch->vcc_active = active;
break;
case CARD_IO_CLK:
if (active == 1 && ch->state == ISO_S_WAIT_CLK)
card_set_state(ch, ISO_S_WAIT_RST);
ch->clocked = active;
break;
case CARD_IO_RST:
if (active == 0 && ch->in_reset &&
ch->vcc_active && ch->clocked) {
/* enable the TC/ETU counter once reset has been released */
tc_etu_enable(ch->tc_chan);
card_set_state(ch, ISO_S_WAIT_ATR);
/* FIXME: wait 400 to 40k clock cycles before sending ATR */
card_set_state(ch, ISO_S_IN_ATR);
} else if (active) {
tc_etu_disable(ch->tc_chan);
}
ch->in_reset = active;
break;
}
}
/* User sets a new ATR to be returned during next card reset */
int card_emu_set_atr(struct card_handle *ch, const uint8_t *atr, uint8_t len)
{
if (len > sizeof(ch->atr.atr))
return -1;
memcpy(ch->atr.atr, atr, len);
ch->atr.len = len;
ch->atr.idx = 0;
/* FIXME: race condition with trasmitting ATR to reader? */
return 0;
}
/* hardware driver informs us that one (more) ETU has expired */
void tc_etu_wtime_half_expired(void *handle)
{
struct card_handle *ch = handle;
/* transmit NULL procedure byte well before waiting time expires */
card_emu_uart_tx(ch->uart_chan, ISO7816_3_PB_NULL);
}
/* hardware driver informs us that one (more) ETU has expired */
void tc_etu_wtime_expired(void *handle)
{
}
/* shortest ATR found in smartcard_list.txt */
static const uint8_t default_atr[] = { 0x3B, 0x02, 0x14, 0x50 };
static struct card_handle card_handles[NUM_SLOTS];
struct card_handle *card_emu_init(uint8_t slot_num, uint8_t tc_chan, uint8_t uart_chan)
{
struct card_handle *ch;
if (slot_num >= ARRAY_SIZE(card_handles))
return NULL;
ch = &card_handles[slot_num];
memset(ch, 0, sizeof(*ch));
/* initialize the card_handle with reasonabe defaults */
ch->state = ISO_S_WAIT_POWER;
ch->vcc_active = 0;
ch->in_reset = 1;
ch->clocked = 0;
ch->fi = 0;
ch->di = 1;
ch->wi = ISO7816_3_DEFAULT_WI;
ch->tc_chan = tc_chan;
ch->uart_chan = uart_chan;
ch->waiting_time = ISO7816_3_INIT_WTIME;
ch->atr.idx = 0;
ch->atr.len = sizeof(default_atr);
memcpy(ch->atr.atr, default_atr, ch->atr.len);
ch->pts.state = PTS_S_WAIT_REQ_PTSS;
ch->tpdu.state = TPDU_S_WAIT_CLA;
tc_etu_init(ch->tc_chan, ch);
return ch;
}