firmware/libcommon/source/mode_cardemu.c - simtrace2 - Gitiles

 /* card emulation mode
  *
  * (C) 2015-2017 by Harald Welte <laforge@gnumonks.org>
  * (C) 2018 by sysmocom -s.f.m.c. GmbH, Author: Kevin Redon <kredon@sysmocom.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 "board.h"
 #include "boardver_adc.h"
 #include "simtrace.h"
 #include "ringbuffer.h"
 #include "card_emu.h"
 #include "iso7816_fidi.h"
 #include "utils.h"
 #include <osmocom/core/linuxlist.h>
 #include <osmocom/core/msgb.h>
 #include "llist_irqsafe.h"
 #include "usb_buf.h"
 #include "simtrace_usb.h"
 #include "simtrace_prot.h"
 #include "sim_switch.h"

 #define TRACE_ENTRY()	TRACE_DEBUG("%s entering\r\n", __func__)

 #ifdef PINS_CARDSIM
 static const Pin pins_cardsim[] = PINS_CARDSIM;
 #endif

 /* UART pins */
 static const Pin pins_usim1[]	= {PINS_USIM1};
 static const Pin pin_usim1_rst	= PIN_USIM1_nRST;
 static const Pin pin_usim1_vcc	= PIN_USIM1_VCC;

 #ifdef CARDEMU_SECOND_UART
 static const Pin pins_usim2[]	= {PINS_USIM2};
 static const Pin pin_usim2_rst	= PIN_USIM2_nRST;
 static const Pin pin_usim2_vcc	= PIN_USIM2_VCC;
 #endif

 struct cardem_inst {
 	unsigned int num;
 	struct card_handle *ch;
 	struct llist_head usb_out_queue;
 	struct ringbuf rb;
 	struct Usart_info usart_info;
 	int usb_pending_old;
 	uint8_t ep_out;
 	uint8_t ep_in;
 	uint8_t ep_int;
 	const Pin pin_insert;
 	uint32_t vcc_uv;
 	uint32_t vcc_uv_last;
 };

 struct cardem_inst cardem_inst[] = {
 	{
 		.num = 0,
 		.usart_info = 	{
 			.base = USART1,
 			.id = ID_USART1,
 			.state = USART_RCV
 		},
 		.ep_out = SIMTRACE_CARDEM_USB_EP_USIM1_DATAOUT,
 		.ep_in = SIMTRACE_CARDEM_USB_EP_USIM1_DATAIN,
 		.ep_int = SIMTRACE_CARDEM_USB_EP_USIM1_INT,
 #ifdef PIN_SET_USIM1_PRES
 		.pin_insert = PIN_SET_USIM1_PRES,
 #endif
 	},
 #ifdef CARDEMU_SECOND_UART
 	{
 		.num = 1,
 		.usart_info = {
 			.base = USART0,
 			.id = ID_USART0,
 			.state = USART_RCV
 		},
 		.ep_out = SIMTRACE_CARDEM_USB_EP_USIM2_DATAOUT,
 		.ep_in = SIMTRACE_CARDEM_USB_EP_USIM2_DATAIN,
 		.ep_int = SIMTRACE_CARDEM_USB_EP_USIM2_INT,
 #ifdef PIN_SET_USIM2_PRES
 		.pin_insert = PIN_SET_USIM2_PRES,
 #endif
 	},
 #endif
 };

 static Usart *get_usart_by_chan(uint8_t uart_chan)
 {
 	if (uart_chan < ARRAY_SIZE(cardem_inst)) {
 		return cardem_inst[uart_chan].usart_info.base;
 	} else {
 		return NULL;
 	}
 }

 /***********************************************************************
  * Call-Backs from card_emu.c
  ***********************************************************************/

 static void wait_tx_idle(Usart *usart)
 {
 	int i = 1;

 	/* wait until last char has been fully transmitted */
 	while ((usart->US_CSR & (US_CSR_TXEMPTY)) == 0) {
 		if (!(i%1000000)) {
 			TRACE_ERROR("s: %lx \r\n", usart->US_CSR);
 		}
 		i++;
 	}
 }

 void card_emu_uart_wait_tx_idle(uint8_t uart_chan)
 {
 	Usart *usart = get_usart_by_chan(uart_chan);
 	wait_tx_idle(usart);
 }

 /* call-back from card_emu.c to enable/disable transmit and/or receive */
 void card_emu_uart_enable(uint8_t uart_chan, uint8_t rxtx)
 {
 	Usart *usart = get_usart_by_chan(uart_chan);
 	switch (rxtx) {
 	case ENABLE_TX:
 		USART_DisableIt(usart, ~US_IER_TXRDY);
 		/* as irritating as it is, we actually want to keep the
 		 * receiver enabled during transmit */
 		USART_SetReceiverEnabled(usart, 1);
 		usart->US_CR = US_CR_RSTSTA | US_CR_RSTIT | US_CR_RSTNACK;
 		USART_EnableIt(usart, US_IER_TXRDY);
 		USART_SetTransmitterEnabled(usart, 1);
 		break;
 	case ENABLE_RX:
 		USART_DisableIt(usart, ~US_IER_RXRDY);
 		/* as irritating as it is, we actually want to keep the
 		 * transmitter enabled during receive */
 		USART_SetTransmitterEnabled(usart, 1);
 		wait_tx_idle(usart);
 		usart->US_CR = US_CR_RSTSTA | US_CR_RSTIT | US_CR_RSTNACK;
 		USART_EnableIt(usart, US_IER_RXRDY);
 		USART_SetReceiverEnabled(usart, 1);
 		break;
 	case 0:
 	default:
 		USART_SetTransmitterEnabled(usart, 0);
 		USART_SetReceiverEnabled(usart, 0);
 		USART_DisableIt(usart, 0xFFFFFFFF);
 		usart->US_CR = US_CR_RSTSTA | US_CR_RSTIT | US_CR_RSTNACK;
 		break;
 	}
 }

 /* call-back from card_emu.c to transmit a byte */
 int card_emu_uart_tx(uint8_t uart_chan, uint8_t byte)
 {
 	Usart *usart = get_usart_by_chan(uart_chan);
 #if 0
 	Usart_info *ui = &usart_info[uart_chan];
 	ISO7816_SendChar(byte, ui);
 #else
 	int i = 1;
 	while ((usart->US_CSR & (US_CSR_TXRDY)) == 0) {
 		if (!(i%1000000)) {
 			TRACE_ERROR("%u: s: %lx %02lX\r\n",
 				uart_chan, usart->US_CSR,
 				usart->US_RHR & 0xFF);
 			usart->US_CR = US_CR_RSTTX;
 			usart->US_CR = US_CR_RSTRX;
 		}
 		i++;
 	}
 	usart->US_THR = byte;
 	//TRACE_ERROR("Sx%02x\r\n", byte);
 #endif
 	return 1;
 }


 /* FIXME: integrate this with actual irq handler */
 static void usart_irq_rx(uint8_t inst_num)
 {
 	Usart *usart = get_usart_by_chan(inst_num);
 	struct cardem_inst *ci = &cardem_inst[inst_num];
 	uint32_t csr;
 	uint8_t byte = 0;

 	csr = usart->US_CSR & usart->US_IMR;

 	if (csr & US_CSR_RXRDY) {
 		byte = (usart->US_RHR) & 0xFF;
 		if (rbuf_write(&ci->rb, byte) < 0)
 			TRACE_ERROR("rbuf overrun\r\n");
 	}

 	if (csr & US_CSR_TXRDY) {
 		if (card_emu_tx_byte(ci->ch) == 0)
 			USART_DisableIt(usart, US_IER_TXRDY);
 	}

 	if (csr & (US_CSR_OVRE|US_CSR_FRAME|US_CSR_PARE|
 		   US_CSR_TIMEOUT|US_CSR_NACK|(1<<10))) {
 		usart->US_CR = US_CR_RSTSTA | US_CR_RSTIT | US_CR_RSTNACK;
 		TRACE_ERROR("%u e 0x%x st: 0x%lx\n", ci->num, byte, csr);
 	}
 }

 void mode_cardemu_usart0_irq(void)
 {
 	/* USART0 == Instance 1 == USIM 2 */
 	usart_irq_rx(1);
 }

 void mode_cardemu_usart1_irq(void)
 {
 	/* USART1 == Instance 0 == USIM 1 */
 	usart_irq_rx(0);
 }

 /* call-back from card_emu.c to change UART baud rate */
 int card_emu_uart_update_fidi(uint8_t uart_chan, unsigned int fidi)
 {
 	int rc;
 	Usart *usart = get_usart_by_chan(uart_chan);

 	usart->US_CR |= US_CR_RXDIS | US_CR_RSTRX;
 	usart->US_FIDI = fidi & 0x3ff;
 	usart->US_CR |= US_CR_RXEN | US_CR_STTTO;
 	return 0;
 }

 /* call-back from card_emu.c to force a USART interrupt */
 void card_emu_uart_interrupt(uint8_t uart_chan)
 {
 	Usart *usart = get_usart_by_chan(uart_chan);
 	if (!usart) {
 		return;
 	}
 	if (USART0 == usart) {
 		NVIC_SetPendingIRQ(USART0_IRQn);
 	} else if (USART1 == usart) {
 		NVIC_SetPendingIRQ(USART1_IRQn);
 	}
 }

 /***********************************************************************
  * ADC for VCC voltage detection
  ***********************************************************************/

 #ifdef DETECT_VCC_BY_ADC

 static int adc_triggered = 0;
 static int adc_sam3s_reva_errata = 0;

 static int card_vcc_adc_init(void)
 {
 	uint32_t chip_arch = CHIPID->CHIPID_CIDR & CHIPID_CIDR_ARCH_Msk;
 	uint32_t chip_ver = CHIPID->CHIPID_CIDR & CHIPID_CIDR_VERSION_Msk;

 	PMC_EnablePeripheral(ID_ADC);

 	ADC->ADC_CR |= ADC_CR_SWRST;
 	if (chip_ver == 0 &&
 	    (chip_arch == CHIPID_CIDR_ARCH_SAM3SxA ||
 	     chip_arch == CHIPID_CIDR_ARCH_SAM3SxB ||
 	     chip_arch == CHIPID_CIDR_ARCH_SAM3SxC)) {
 		TRACE_INFO("Enabling Rev.A ADC Errata work-around\r\n");
 		adc_sam3s_reva_errata = 1;
 	}

 	if (adc_sam3s_reva_errata) {
 		/* Errata Work-Around to clear EOCx flags */
 		volatile uint32_t foo;
 		int i;
 		for (i = 0; i < 16; i++)
 			foo = ADC->ADC_CDR[i];
 	}

 	/* Initialize ADC for AD7 / AD6, fADC=48/24=2MHz */
 	ADC->ADC_MR = ADC_MR_TRGEN_DIS | ADC_MR_LOWRES_BITS_12 |
 		      ADC_MR_SLEEP_NORMAL | ADC_MR_FWUP_OFF |
 		      ADC_MR_FREERUN_OFF | ADC_MR_PRESCAL(23) |
 		      ADC_MR_STARTUP_SUT8 | ADC_MR_SETTLING(3) |
 		      ADC_MR_ANACH_NONE | ADC_MR_TRACKTIM(4) |
 		      ADC_MR_TRANSFER(1) | ADC_MR_USEQ_NUM_ORDER;
 	/* enable AD6 + AD7 channels */
 	ADC->ADC_CHER = ADC_CHER_CH7;
 	ADC->ADC_IER = ADC_IER_EOC7;
 #ifdef CARDEMU_SECOND_UART
 	ADC->ADC_CHER |= ADC_CHER_CH6;
 	ADC->ADC_IER |= ADC_IER_EOC6;
 #endif
 	NVIC_EnableIRQ(ADC_IRQn);
 	ADC->ADC_CR |= ADC_CR_START;

 	return 0;
 }

 #define VCC_UV_THRESH_1V8	1500000
 #define VCC_UV_THRESH_3V	2500000

 static void process_vcc_adc(struct cardem_inst *ci)
 {
 	if (ci->vcc_uv >= VCC_UV_THRESH_3V &&
 	    ci->vcc_uv_last < VCC_UV_THRESH_3V) {
 		card_emu_io_statechg(ci->ch, CARD_IO_VCC, 1);
 		/* FIXME do this for real */
 		card_emu_io_statechg(ci->ch, CARD_IO_CLK, 1);
 	} else if (ci->vcc_uv < VCC_UV_THRESH_3V &&
 		 ci->vcc_uv_last >= VCC_UV_THRESH_3V) {
 		/* FIXME do this for real */
 		card_emu_io_statechg(ci->ch, CARD_IO_CLK, 0);
 		card_emu_io_statechg(ci->ch, CARD_IO_VCC, 0);
 	}
 	ci->vcc_uv_last = ci->vcc_uv;
 }

 void ADC_IrqHandler(void)
 {
 #ifdef CARDEMU_SECOND_UART
 	if (ADC->ADC_ISR & ADC_ISR_EOC6) {
 		uint16_t val = ADC->ADC_CDR[6] & 0xFFF;
 		cardem_inst[1].vcc_uv = adc2uv(val);
 		process_vcc_adc(&cardem_inst[1]);
 		if (adc_sam3s_reva_errata) {
 			/* Errata: START doesn't start a conversion
 			 * sequence, but only a single conversion */
 			ADC->ADC_CR |= ADC_CR_START;
 		}
 	}
 #endif

 	if (ADC->ADC_ISR & ADC_ISR_EOC7) {
 		uint16_t val = ADC->ADC_CDR[7] & 0xFFF;
 		cardem_inst[0].vcc_uv = adc2uv(val);
 		process_vcc_adc(&cardem_inst[0]);
 		ADC->ADC_CR |= ADC_CR_START;
 	}
 }
 #endif /* DETECT_VCC_BY_ADC */

 /***********************************************************************
  * Core USB  / main loop integration
  ***********************************************************************/

 static void usim1_rst_irqhandler(const Pin *pPin)
 {
 	bool active = PIO_Get(&pin_usim1_rst) ? false : true;
 	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_RST, active);
 }

 #ifndef DETECT_VCC_BY_ADC
 static void usim1_vcc_irqhandler(const Pin *pPin)
 {
 	bool active = PIO_Get(&pin_usim1_vcc) ? true : false;
 	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_VCC, active);
 	/* FIXME do this for real */
 	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_CLK, active);
 }
 #endif /* !DETECT_VCC_BY_ADC */

 #ifdef CARDEMU_SECOND_UART
 static void usim2_rst_irqhandler(const Pin *pPin)
 {
 	bool active = PIO_Get(&pin_usim2_rst) ? false : true;
 	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_RST, active);
 }

 #ifndef DETECT_VCC_BY_ADC
 static void usim2_vcc_irqhandler(const Pin *pPin)
 {
 	bool active = PIO_Get(&pin_usim2_vcc) ? true : false;
 	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_VCC, active);
 	/* FIXME do this for real */
 	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_CLK, active);
 }
 #endif /* !DETECT_VCC_BY_ADC */
 #endif /* CARDEMU_SECOND_UART */

 /* executed once at system boot for each config */
 void mode_cardemu_configure(void)
 {
 	TRACE_ENTRY();
 }

 /* called if config is activated */
 void mode_cardemu_init(void)
 {
 	int i;

 	TRACE_ENTRY();

 #ifdef PINS_CARDSIM
 	PIO_Configure(pins_cardsim, PIO_LISTSIZE(pins_cardsim));
 #endif
 #ifdef DETECT_VCC_BY_ADC
 	card_vcc_adc_init();
 #endif /* DETECT_VCC_BY_ADC */

 	INIT_LLIST_HEAD(&cardem_inst[0].usb_out_queue);
 	rbuf_reset(&cardem_inst[0].rb);
 	PIO_Configure(pins_usim1, PIO_LISTSIZE(pins_usim1));
 	ISO7816_Init(&cardem_inst[0].usart_info, CLK_SLAVE);
 	NVIC_EnableIRQ(USART1_IRQn);
 	PIO_ConfigureIt(&pin_usim1_rst, usim1_rst_irqhandler);
 	PIO_EnableIt(&pin_usim1_rst);
 #ifndef DETECT_VCC_BY_ADC
 	PIO_ConfigureIt(&pin_usim1_vcc, usim1_vcc_irqhandler);
 	PIO_EnableIt(&pin_usim1_vcc);
 #endif /* DETECT_VCC_BY_ADC */
 	cardem_inst[0].ch = card_emu_init(0, 2, 0, SIMTRACE_CARDEM_USB_EP_USIM1_DATAIN, SIMTRACE_CARDEM_USB_EP_USIM1_INT, PIO_Get(&pin_usim1_vcc) ? true : false, PIO_Get(&pin_usim1_rst) ? false : true, PIO_Get(&pin_usim1_vcc) ? true : false);
 	sim_switch_use_physical(0, 1);

 #ifdef CARDEMU_SECOND_UART
 	INIT_LLIST_HEAD(&cardem_inst[1].usb_out_queue);
 	rbuf_reset(&cardem_inst[1].rb);
 	PIO_Configure(pins_usim2, PIO_LISTSIZE(pins_usim2));
 	ISO7816_Init(&cardem_inst[1].usart_info, CLK_SLAVE);
 	NVIC_EnableIRQ(USART0_IRQn);
 	PIO_ConfigureIt(&pin_usim2_rst, usim2_rst_irqhandler);
 	PIO_EnableIt(&pin_usim2_rst);
 #ifndef DETECT_VCC_BY_ADC
 	PIO_ConfigureIt(&pin_usim2_vcc, usim2_vcc_irqhandler);
 	PIO_EnableIt(&pin_usim2_vcc);
 #endif /* DETECT_VCC_BY_ADC */
 	cardem_inst[1].ch = card_emu_init(1, 0, 1, SIMTRACE_CARDEM_USB_EP_USIM2_DATAIN, SIMTRACE_CARDEM_USB_EP_USIM2_INT, PIO_Get(&pin_usim2_vcc) ? true : false, PIO_Get(&pin_usim2_rst) ? false : true, PIO_Get(&pin_usim2_vcc) ? true : false);
 	sim_switch_use_physical(1, 1);
 #endif /* CARDEMU_SECOND_UART */
 }

 /* called if config is deactivated */
 void mode_cardemu_exit(void)
 {
 	TRACE_ENTRY();

 	/* FIXME: stop tc_fdt */
 	/* FIXME: release all msg, unlink them from any queue */

 	PIO_DisableIt(&pin_usim1_rst);
 	PIO_DisableIt(&pin_usim1_vcc);

 	NVIC_DisableIRQ(USART1_IRQn);
 	USART_SetTransmitterEnabled(USART1, 0);
 	USART_SetReceiverEnabled(USART1, 0);

 #ifdef CARDEMU_SECOND_UART
 	PIO_DisableIt(&pin_usim2_rst);
 	PIO_DisableIt(&pin_usim2_vcc);

 	NVIC_DisableIRQ(USART0_IRQn);
 	USART_SetTransmitterEnabled(USART0, 0);
 	USART_SetReceiverEnabled(USART0, 0);
 #endif
 }

 /* handle a single USB command as received from the USB host */
 static void dispatch_usb_command_generic(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct simtrace_msg_hdr *hdr;

 	hdr = (struct simtrace_msg_hdr *) msg->l1h;
 	switch (hdr->msg_type) {
 	case SIMTRACE_CMD_BD_BOARD_INFO:
 		break;
 	default:
 		break;
 	}
 	usb_buf_free(msg);
 }

 /* handle a single USB command as received from the USB host */
 static void dispatch_usb_command_cardem(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct simtrace_msg_hdr *hdr;
 	struct cardemu_usb_msg_set_atr *atr;
 	struct cardemu_usb_msg_cardinsert *cardins;
 	struct llist_head *queue;

 	hdr = (struct simtrace_msg_hdr *) msg->l1h;
 	switch (hdr->msg_type) {
 	case SIMTRACE_MSGT_DT_CEMU_TX_DATA:
 		queue = card_emu_get_uart_tx_queue(ci->ch);
 		llist_add_tail(&msg->list, queue);
 		card_emu_have_new_uart_tx(ci->ch);
 		break;
 	case SIMTRACE_MSGT_DT_CEMU_SET_ATR:
 		atr = (struct cardemu_usb_msg_set_atr *) msg->l2h;
 		card_emu_set_atr(ci->ch, atr->atr, atr->atr_len);
 		usb_buf_free(msg);
 		break;
 	case SIMTRACE_MSGT_DT_CEMU_CARDINSERT:
 		cardins = (struct cardemu_usb_msg_cardinsert *) msg->l2h;
 		if (!ci->pin_insert.pio) {
 			TRACE_INFO("%u: skipping unsupported card_insert to %s\r\n",
 				   ci->num, cardins->card_insert ? "INSERTED" : "REMOVED");
 			break;
 		}
 		TRACE_INFO("%u: set card_insert to %s\r\n", ci->num,
 			   cardins->card_insert ? "INSERTED" : "REMOVED");
 		if (cardins->card_insert)
 			PIO_Set(&ci->pin_insert);
 		else
 			PIO_Clear(&ci->pin_insert);
 		usb_buf_free(msg);
 		break;
 	case SIMTRACE_MSGT_BD_CEMU_STATUS:
 		card_emu_report_status(ci->ch);
 		usb_buf_free(msg);
 		break;
 	case SIMTRACE_MSGT_BD_CEMU_STATS:
 	default:
 		/* FIXME: Send Error */
 		usb_buf_free(msg);
 		break;
 	}
 }

 #ifdef PINS_PERST
 #include "wwan_perst.h"
 #endif

 static int usb_command_modem_reset(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct st_modem_reset *mr = (struct st_modem_reset *) msg->l2h;

 	if (msgb_l2len(msg) < sizeof(*mr))
 		return -1;

 	switch (mr->asserted) {
 #ifdef PINS_PERST
 	case 0:
 		wwan_perst_set(ci->num, 0);
 		break;
 	case 1:
 		wwan_perst_set(ci->num, 1);
 		break;
 	case 2:
 		wwan_perst_do_reset_pulse(ci->num, mr->pulse_duration_msec);
 		break;
 #endif
 	default:
 		return -1;
 	}

 	return 0;
 }

 static int usb_command_sim_select(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct st_modem_sim_select *mss = (struct st_modem_sim_select *) msg->l2h;

 	if (msgb_l2len(msg) < sizeof(*mss))
 		return -1;

 	if (mss->remote_sim)
 		sim_switch_use_physical(ci->num, 0);
 	else
 		sim_switch_use_physical(ci->num, 1);

 	return 0;
 }

 /* handle a single USB command as received from the USB host */
 static void dispatch_usb_command_modem(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct simtrace_msg_hdr *hdr;

 	hdr = (struct simtrace_msg_hdr *) msg->l1h;
 	switch (hdr->msg_type) {
 	case SIMTRACE_MSGT_DT_MODEM_RESET:
 		usb_command_modem_reset(msg, ci);
 		break;
 	case SIMTRACE_MSGT_DT_MODEM_SIM_SELECT:
 		usb_command_sim_select(msg, ci);
 		break;
 	case SIMTRACE_MSGT_BD_MODEM_STATUS:
 		break;
 	default:
 		break;
 	}
 	usb_buf_free(msg);
 }

 /* handle a single USB command as received from the USB host */
 static void dispatch_usb_command(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct simtrace_msg_hdr *sh = (struct simtrace_msg_hdr *) msg->l1h;

 	if (msgb_length(msg) < sizeof(*sh)) {
 		/* FIXME: Error */
 		usb_buf_free(msg);
 		return;
 	}
 	msg->l2h = msg->l1h + sizeof(*sh);

 	switch (sh->msg_class) {
 	case SIMTRACE_MSGC_GENERIC:
 		dispatch_usb_command_generic(msg, ci);
 		break;
 	case SIMTRACE_MSGC_CARDEM:
 		dispatch_usb_command_cardem(msg, ci);
 		break;
 	case SIMTRACE_MSGC_MODEM:
 		/* FIXME: Find out why this fails if used for !=
 		 * MSGC_MODEM ?!? */
 		dispatch_usb_command_modem(msg, ci);
 		break;
 	default:
 		/* FIXME: Send Error */
 		usb_buf_free(msg);
 		break;
 	}
 }

 static void dispatch_received_msg(struct msgb *msg, struct cardem_inst *ci)
 {
 	struct msgb *segm;
 	struct simtrace_msg_hdr *mh;

 	/* check if we have multiple concatenated commands in
 	 * one message.  USB endpoints are streams that don't
 	 * preserve the message boundaries */
 	mh = (struct simtrace_msg_hdr *) msg->data;
 	if (mh->msg_len == msgb_length(msg)) {
 		/* fast path: only one message in buffer */
 		dispatch_usb_command(msg, ci);
 		return;
 	}

 	/* slow path: iterate over list of messages, allocating one new
 	 * reqe_ctx per segment */
 	while (1) {
 		mh = (struct simtrace_msg_hdr *) msg->data;

 		segm = usb_buf_alloc(ci->ep_out);
 		if (!segm) {
 			TRACE_ERROR("%u: ENOMEM during msg segmentation\r\n",
 				    ci->num);
 			break;
 		}

 		if (mh->msg_len > msgb_length(msg)) {
 			TRACE_ERROR("%u: Unexpected large message (%u bytes)\n",
 					ci->num, mh->msg_len);
 			usb_buf_free(segm);
 		} else {
 			uint8_t *cur = msgb_put(segm, mh->msg_len);
 			segm->l1h = segm->head;
 			memcpy(cur, mh, mh->msg_len);
 			dispatch_usb_command(segm, ci);
 		}
 		/* pull this message */
 		msgb_pull(msg, mh->msg_len);
 		/* abort if we're done */
 		if (msgb_length(msg) <= 0)
 			break;
 	}

 	usb_buf_free(msg);
 }

 /* iterate over the queue of incoming USB commands and dispatch/execute
  * them */
 static void process_any_usb_commands(struct llist_head *main_q,
 				     struct cardem_inst *ci)
 {
 	struct llist_head *lh;
 	struct msgb *msg;
 	int i;

 	/* limit the number of iterations to 10, to ensure we don't get
 	 * stuck here without returning to main loop processing */
 	for (i = 0; i < 10; i++) {
 		/* de-queue the list head in an irq-safe way */
 		lh = llist_head_dequeue_irqsafe(main_q);
 		if (!lh)
 			break;
 		msg = llist_entry(lh, struct msgb, list);
 		dispatch_received_msg(msg, ci);
 	}
 }

 /* main loop function, called repeatedly */
 void mode_cardemu_run(void)
 {
 	struct llist_head *queue;
 	unsigned int i;

 	for (i = 0; i < ARRAY_SIZE(cardem_inst); i++) {
 		struct cardem_inst *ci = &cardem_inst[i];

 		/* drain the ring buffer from UART into card_emu */
 		while (1) {
 			__disable_irq();
 			if (rbuf_is_empty(&ci->rb)) {
 				__enable_irq();
 				break;
 			}
 			uint8_t byte = rbuf_read(&ci->rb);
 			__enable_irq();
 			card_emu_process_rx_byte(ci->ch, byte);
 			//TRACE_ERROR("%uRx%02x\r\n", i, byte);
 		}

 		/* first try to send any pending messages on IRQ */
 		usb_refill_to_host(ci->ep_int);

 		/* then try to send any pending messages on IN */
 		usb_refill_to_host(ci->ep_in);

 		/* ensure we can handle incoming USB messages from the
 		 * host */
 		usb_refill_from_host(ci->ep_out);
 		queue = usb_get_queue(ci->ep_out);
 		process_any_usb_commands(queue, ci);
 	}
 }
	/* card emulation mode
	*
	* (C) 2015-2017 by Harald Welte <laforge@gnumonks.org>
	* (C) 2018 by sysmocom -s.f.m.c. GmbH, Author: Kevin Redon <kredon@sysmocom.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 "board.h"
	#include "boardver_adc.h"
	#include "simtrace.h"
	#include "ringbuffer.h"
	#include "card_emu.h"
	#include "iso7816_fidi.h"
	#include "utils.h"
	#include <osmocom/core/linuxlist.h>
	#include <osmocom/core/msgb.h>
	#include "llist_irqsafe.h"
	#include "usb_buf.h"
	#include "simtrace_usb.h"
	#include "simtrace_prot.h"
	#include "sim_switch.h"

	#define TRACE_ENTRY() TRACE_DEBUG("%s entering\r\n", __func__)

	#ifdef PINS_CARDSIM
	static const Pin pins_cardsim[] = PINS_CARDSIM;
	#endif

	/* UART pins */
	static const Pin pins_usim1[] = {PINS_USIM1};
	static const Pin pin_usim1_rst = PIN_USIM1_nRST;
	static const Pin pin_usim1_vcc = PIN_USIM1_VCC;

	#ifdef CARDEMU_SECOND_UART
	static const Pin pins_usim2[] = {PINS_USIM2};
	static const Pin pin_usim2_rst = PIN_USIM2_nRST;
	static const Pin pin_usim2_vcc = PIN_USIM2_VCC;
	#endif

	struct cardem_inst {
	unsigned int num;
	struct card_handle *ch;
	struct llist_head usb_out_queue;
	struct ringbuf rb;
	struct Usart_info usart_info;
	int usb_pending_old;
	uint8_t ep_out;
	uint8_t ep_in;
	uint8_t ep_int;
	const Pin pin_insert;
	uint32_t vcc_uv;
	uint32_t vcc_uv_last;
	};

	struct cardem_inst cardem_inst[] = {
	{
	.num = 0,
	.usart_info = {
	.base = USART1,
	.id = ID_USART1,
	.state = USART_RCV
	},
	.ep_out = SIMTRACE_CARDEM_USB_EP_USIM1_DATAOUT,
	.ep_in = SIMTRACE_CARDEM_USB_EP_USIM1_DATAIN,
	.ep_int = SIMTRACE_CARDEM_USB_EP_USIM1_INT,
	#ifdef PIN_SET_USIM1_PRES
	.pin_insert = PIN_SET_USIM1_PRES,
	#endif
	},
	#ifdef CARDEMU_SECOND_UART
	{
	.num = 1,
	.usart_info = {
	.base = USART0,
	.id = ID_USART0,
	.state = USART_RCV
	},
	.ep_out = SIMTRACE_CARDEM_USB_EP_USIM2_DATAOUT,
	.ep_in = SIMTRACE_CARDEM_USB_EP_USIM2_DATAIN,
	.ep_int = SIMTRACE_CARDEM_USB_EP_USIM2_INT,
	#ifdef PIN_SET_USIM2_PRES
	.pin_insert = PIN_SET_USIM2_PRES,
	#endif
	},
	#endif
	};

	static Usart *get_usart_by_chan(uint8_t uart_chan)
	{
	if (uart_chan < ARRAY_SIZE(cardem_inst)) {
	return cardem_inst[uart_chan].usart_info.base;
	} else {
	return NULL;
	}
	}

	/***********************************************************************
	* Call-Backs from card_emu.c
	***********************************************************************/

	static void wait_tx_idle(Usart *usart)
	{
	int i = 1;

	/* wait until last char has been fully transmitted */
	while ((usart->US_CSR & (US_CSR_TXEMPTY)) == 0) {
	if (!(i%1000000)) {
	TRACE_ERROR("s: %lx \r\n", usart->US_CSR);
	}
	i++;
	}
	}

	void card_emu_uart_wait_tx_idle(uint8_t uart_chan)
	{
	Usart *usart = get_usart_by_chan(uart_chan);
	wait_tx_idle(usart);
	}

	/* call-back from card_emu.c to enable/disable transmit and/or receive */
	void card_emu_uart_enable(uint8_t uart_chan, uint8_t rxtx)
	{
	Usart *usart = get_usart_by_chan(uart_chan);
	switch (rxtx) {
	case ENABLE_TX:
	USART_DisableIt(usart, ~US_IER_TXRDY);
	/* as irritating as it is, we actually want to keep the
	* receiver enabled during transmit */
	USART_SetReceiverEnabled(usart, 1);
	usart->US_CR = US_CR_RSTSTA \| US_CR_RSTIT \| US_CR_RSTNACK;
	USART_EnableIt(usart, US_IER_TXRDY);
	USART_SetTransmitterEnabled(usart, 1);
	break;
	case ENABLE_RX:
	USART_DisableIt(usart, ~US_IER_RXRDY);
	/* as irritating as it is, we actually want to keep the
	* transmitter enabled during receive */
	USART_SetTransmitterEnabled(usart, 1);
	wait_tx_idle(usart);
	usart->US_CR = US_CR_RSTSTA \| US_CR_RSTIT \| US_CR_RSTNACK;
	USART_EnableIt(usart, US_IER_RXRDY);
	USART_SetReceiverEnabled(usart, 1);
	break;
	case 0:
	default:
	USART_SetTransmitterEnabled(usart, 0);
	USART_SetReceiverEnabled(usart, 0);
	USART_DisableIt(usart, 0xFFFFFFFF);
	usart->US_CR = US_CR_RSTSTA \| US_CR_RSTIT \| US_CR_RSTNACK;
	break;
	}
	}

	/* call-back from card_emu.c to transmit a byte */
	int card_emu_uart_tx(uint8_t uart_chan, uint8_t byte)
	{
	Usart *usart = get_usart_by_chan(uart_chan);
	#if 0
	Usart_info *ui = &usart_info[uart_chan];
	ISO7816_SendChar(byte, ui);
	#else
	int i = 1;
	while ((usart->US_CSR & (US_CSR_TXRDY)) == 0) {
	if (!(i%1000000)) {
	TRACE_ERROR("%u: s: %lx %02lX\r\n",
	uart_chan, usart->US_CSR,
	usart->US_RHR & 0xFF);
	usart->US_CR = US_CR_RSTTX;
	usart->US_CR = US_CR_RSTRX;
	}
	i++;
	}
	usart->US_THR = byte;
	//TRACE_ERROR("Sx%02x\r\n", byte);
	#endif
	return 1;
	}


	/* FIXME: integrate this with actual irq handler */
	static void usart_irq_rx(uint8_t inst_num)
	{
	Usart *usart = get_usart_by_chan(inst_num);
	struct cardem_inst *ci = &cardem_inst[inst_num];
	uint32_t csr;
	uint8_t byte = 0;

	csr = usart->US_CSR & usart->US_IMR;

	if (csr & US_CSR_RXRDY) {
	byte = (usart->US_RHR) & 0xFF;
	if (rbuf_write(&ci->rb, byte) < 0)
	TRACE_ERROR("rbuf overrun\r\n");
	}

	if (csr & US_CSR_TXRDY) {
	if (card_emu_tx_byte(ci->ch) == 0)
	USART_DisableIt(usart, US_IER_TXRDY);
	}

	if (csr & (US_CSR_OVRE\|US_CSR_FRAME\|US_CSR_PARE\|
	US_CSR_TIMEOUT\|US_CSR_NACK\|(1<<10))) {
	usart->US_CR = US_CR_RSTSTA \| US_CR_RSTIT \| US_CR_RSTNACK;
	TRACE_ERROR("%u e 0x%x st: 0x%lx\n", ci->num, byte, csr);
	}
	}

	void mode_cardemu_usart0_irq(void)
	{
	/* USART0 == Instance 1 == USIM 2 */
	usart_irq_rx(1);
	}

	void mode_cardemu_usart1_irq(void)
	{
	/* USART1 == Instance 0 == USIM 1 */
	usart_irq_rx(0);
	}

	/* call-back from card_emu.c to change UART baud rate */
	int card_emu_uart_update_fidi(uint8_t uart_chan, unsigned int fidi)
	{
	int rc;
	Usart *usart = get_usart_by_chan(uart_chan);

	usart->US_CR \|= US_CR_RXDIS \| US_CR_RSTRX;
	usart->US_FIDI = fidi & 0x3ff;
	usart->US_CR \|= US_CR_RXEN \| US_CR_STTTO;
	return 0;
	}

	/* call-back from card_emu.c to force a USART interrupt */
	void card_emu_uart_interrupt(uint8_t uart_chan)
	{
	Usart *usart = get_usart_by_chan(uart_chan);
	if (!usart) {
	return;
	}
	if (USART0 == usart) {
	NVIC_SetPendingIRQ(USART0_IRQn);
	} else if (USART1 == usart) {
	NVIC_SetPendingIRQ(USART1_IRQn);
	}
	}

	/***********************************************************************
	* ADC for VCC voltage detection
	***********************************************************************/

	#ifdef DETECT_VCC_BY_ADC

	static int adc_triggered = 0;
	static int adc_sam3s_reva_errata = 0;

	static int card_vcc_adc_init(void)
	{
	uint32_t chip_arch = CHIPID->CHIPID_CIDR & CHIPID_CIDR_ARCH_Msk;
	uint32_t chip_ver = CHIPID->CHIPID_CIDR & CHIPID_CIDR_VERSION_Msk;

	PMC_EnablePeripheral(ID_ADC);

	ADC->ADC_CR \|= ADC_CR_SWRST;
	if (chip_ver == 0 &&
	(chip_arch == CHIPID_CIDR_ARCH_SAM3SxA \|\|
	chip_arch == CHIPID_CIDR_ARCH_SAM3SxB \|\|
	chip_arch == CHIPID_CIDR_ARCH_SAM3SxC)) {
	TRACE_INFO("Enabling Rev.A ADC Errata work-around\r\n");
	adc_sam3s_reva_errata = 1;
	}

	if (adc_sam3s_reva_errata) {
	/* Errata Work-Around to clear EOCx flags */
	volatile uint32_t foo;
	int i;
	for (i = 0; i < 16; i++)
	foo = ADC->ADC_CDR[i];
	}

	/* Initialize ADC for AD7 / AD6, fADC=48/24=2MHz */
	ADC->ADC_MR = ADC_MR_TRGEN_DIS \| ADC_MR_LOWRES_BITS_12 \|
	ADC_MR_SLEEP_NORMAL \| ADC_MR_FWUP_OFF \|
	ADC_MR_FREERUN_OFF \| ADC_MR_PRESCAL(23) \|
	ADC_MR_STARTUP_SUT8 \| ADC_MR_SETTLING(3) \|
	ADC_MR_ANACH_NONE \| ADC_MR_TRACKTIM(4) \|
	ADC_MR_TRANSFER(1) \| ADC_MR_USEQ_NUM_ORDER;
	/* enable AD6 + AD7 channels */
	ADC->ADC_CHER = ADC_CHER_CH7;
	ADC->ADC_IER = ADC_IER_EOC7;
	#ifdef CARDEMU_SECOND_UART
	ADC->ADC_CHER \|= ADC_CHER_CH6;
	ADC->ADC_IER \|= ADC_IER_EOC6;
	#endif
	NVIC_EnableIRQ(ADC_IRQn);
	ADC->ADC_CR \|= ADC_CR_START;

	return 0;
	}

	#define VCC_UV_THRESH_1V8 1500000
	#define VCC_UV_THRESH_3V 2500000

	static void process_vcc_adc(struct cardem_inst *ci)
	{
	if (ci->vcc_uv >= VCC_UV_THRESH_3V &&
	ci->vcc_uv_last < VCC_UV_THRESH_3V) {
	card_emu_io_statechg(ci->ch, CARD_IO_VCC, 1);
	/* FIXME do this for real */
	card_emu_io_statechg(ci->ch, CARD_IO_CLK, 1);
	} else if (ci->vcc_uv < VCC_UV_THRESH_3V &&
	ci->vcc_uv_last >= VCC_UV_THRESH_3V) {
	/* FIXME do this for real */
	card_emu_io_statechg(ci->ch, CARD_IO_CLK, 0);
	card_emu_io_statechg(ci->ch, CARD_IO_VCC, 0);
	}
	ci->vcc_uv_last = ci->vcc_uv;
	}

	void ADC_IrqHandler(void)
	{
	#ifdef CARDEMU_SECOND_UART
	if (ADC->ADC_ISR & ADC_ISR_EOC6) {
	uint16_t val = ADC->ADC_CDR[6] & 0xFFF;
	cardem_inst[1].vcc_uv = adc2uv(val);
	process_vcc_adc(&cardem_inst[1]);
	if (adc_sam3s_reva_errata) {
	/* Errata: START doesn't start a conversion
	* sequence, but only a single conversion */
	ADC->ADC_CR \|= ADC_CR_START;
	}
	}
	#endif

	if (ADC->ADC_ISR & ADC_ISR_EOC7) {
	uint16_t val = ADC->ADC_CDR[7] & 0xFFF;
	cardem_inst[0].vcc_uv = adc2uv(val);
	process_vcc_adc(&cardem_inst[0]);
	ADC->ADC_CR \|= ADC_CR_START;
	}
	}
	#endif /* DETECT_VCC_BY_ADC */

	/***********************************************************************
	* Core USB / main loop integration
	***********************************************************************/

	static void usim1_rst_irqhandler(const Pin *pPin)
	{
	bool active = PIO_Get(&pin_usim1_rst) ? false : true;
	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_RST, active);
	}

	#ifndef DETECT_VCC_BY_ADC
	static void usim1_vcc_irqhandler(const Pin *pPin)
	{
	bool active = PIO_Get(&pin_usim1_vcc) ? true : false;
	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_VCC, active);
	/* FIXME do this for real */
	card_emu_io_statechg(cardem_inst[0].ch, CARD_IO_CLK, active);
	}
	#endif /* !DETECT_VCC_BY_ADC */

	#ifdef CARDEMU_SECOND_UART
	static void usim2_rst_irqhandler(const Pin *pPin)
	{
	bool active = PIO_Get(&pin_usim2_rst) ? false : true;
	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_RST, active);
	}

	#ifndef DETECT_VCC_BY_ADC
	static void usim2_vcc_irqhandler(const Pin *pPin)
	{
	bool active = PIO_Get(&pin_usim2_vcc) ? true : false;
	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_VCC, active);
	/* FIXME do this for real */
	card_emu_io_statechg(cardem_inst[1].ch, CARD_IO_CLK, active);
	}
	#endif /* !DETECT_VCC_BY_ADC */
	#endif /* CARDEMU_SECOND_UART */

	/* executed once at system boot for each config */
	void mode_cardemu_configure(void)
	{
	TRACE_ENTRY();
	}

	/* called if config is activated */
	void mode_cardemu_init(void)
	{
	int i;

	TRACE_ENTRY();

	#ifdef PINS_CARDSIM
	PIO_Configure(pins_cardsim, PIO_LISTSIZE(pins_cardsim));
	#endif
	#ifdef DETECT_VCC_BY_ADC
	card_vcc_adc_init();
	#endif /* DETECT_VCC_BY_ADC */

	INIT_LLIST_HEAD(&cardem_inst[0].usb_out_queue);
	rbuf_reset(&cardem_inst[0].rb);
	PIO_Configure(pins_usim1, PIO_LISTSIZE(pins_usim1));
	ISO7816_Init(&cardem_inst[0].usart_info, CLK_SLAVE);
	NVIC_EnableIRQ(USART1_IRQn);
	PIO_ConfigureIt(&pin_usim1_rst, usim1_rst_irqhandler);
	PIO_EnableIt(&pin_usim1_rst);
	#ifndef DETECT_VCC_BY_ADC
	PIO_ConfigureIt(&pin_usim1_vcc, usim1_vcc_irqhandler);
	PIO_EnableIt(&pin_usim1_vcc);
	#endif /* DETECT_VCC_BY_ADC */
	cardem_inst[0].ch = card_emu_init(0, 2, 0, SIMTRACE_CARDEM_USB_EP_USIM1_DATAIN, SIMTRACE_CARDEM_USB_EP_USIM1_INT, PIO_Get(&pin_usim1_vcc) ? true : false, PIO_Get(&pin_usim1_rst) ? false : true, PIO_Get(&pin_usim1_vcc) ? true : false);
	sim_switch_use_physical(0, 1);

	#ifdef CARDEMU_SECOND_UART
	INIT_LLIST_HEAD(&cardem_inst[1].usb_out_queue);
	rbuf_reset(&cardem_inst[1].rb);
	PIO_Configure(pins_usim2, PIO_LISTSIZE(pins_usim2));
	ISO7816_Init(&cardem_inst[1].usart_info, CLK_SLAVE);
	NVIC_EnableIRQ(USART0_IRQn);
	PIO_ConfigureIt(&pin_usim2_rst, usim2_rst_irqhandler);
	PIO_EnableIt(&pin_usim2_rst);
	#ifndef DETECT_VCC_BY_ADC
	PIO_ConfigureIt(&pin_usim2_vcc, usim2_vcc_irqhandler);
	PIO_EnableIt(&pin_usim2_vcc);
	#endif /* DETECT_VCC_BY_ADC */
	cardem_inst[1].ch = card_emu_init(1, 0, 1, SIMTRACE_CARDEM_USB_EP_USIM2_DATAIN, SIMTRACE_CARDEM_USB_EP_USIM2_INT, PIO_Get(&pin_usim2_vcc) ? true : false, PIO_Get(&pin_usim2_rst) ? false : true, PIO_Get(&pin_usim2_vcc) ? true : false);
	sim_switch_use_physical(1, 1);
	#endif /* CARDEMU_SECOND_UART */
	}

	/* called if config is deactivated */
	void mode_cardemu_exit(void)
	{
	TRACE_ENTRY();

	/* FIXME: stop tc_fdt */
	/* FIXME: release all msg, unlink them from any queue */

	PIO_DisableIt(&pin_usim1_rst);
	PIO_DisableIt(&pin_usim1_vcc);

	NVIC_DisableIRQ(USART1_IRQn);
	USART_SetTransmitterEnabled(USART1, 0);
	USART_SetReceiverEnabled(USART1, 0);

	#ifdef CARDEMU_SECOND_UART
	PIO_DisableIt(&pin_usim2_rst);
	PIO_DisableIt(&pin_usim2_vcc);

	NVIC_DisableIRQ(USART0_IRQn);
	USART_SetTransmitterEnabled(USART0, 0);
	USART_SetReceiverEnabled(USART0, 0);
	#endif
	}

	/* handle a single USB command as received from the USB host */
	static void dispatch_usb_command_generic(struct msgb msg, struct cardem_inst ci)
	{
	struct simtrace_msg_hdr *hdr;

	hdr = (struct simtrace_msg_hdr *) msg->l1h;
	switch (hdr->msg_type) {
	case SIMTRACE_CMD_BD_BOARD_INFO:
	break;
	default:
	break;
	}
	usb_buf_free(msg);
	}

	/* handle a single USB command as received from the USB host */
	static void dispatch_usb_command_cardem(struct msgb msg, struct cardem_inst ci)
	{
	struct simtrace_msg_hdr *hdr;
	struct cardemu_usb_msg_set_atr *atr;
	struct cardemu_usb_msg_cardinsert *cardins;
	struct llist_head *queue;

	hdr = (struct simtrace_msg_hdr *) msg->l1h;
	switch (hdr->msg_type) {
	case SIMTRACE_MSGT_DT_CEMU_TX_DATA:
	queue = card_emu_get_uart_tx_queue(ci->ch);
	llist_add_tail(&msg->list, queue);
	card_emu_have_new_uart_tx(ci->ch);
	break;
	case SIMTRACE_MSGT_DT_CEMU_SET_ATR:
	atr = (struct cardemu_usb_msg_set_atr *) msg->l2h;
	card_emu_set_atr(ci->ch, atr->atr, atr->atr_len);
	usb_buf_free(msg);
	break;
	case SIMTRACE_MSGT_DT_CEMU_CARDINSERT:
	cardins = (struct cardemu_usb_msg_cardinsert *) msg->l2h;
	if (!ci->pin_insert.pio) {
	TRACE_INFO("%u: skipping unsupported card_insert to %s\r\n",
	ci->num, cardins->card_insert ? "INSERTED" : "REMOVED");
	break;
	}
	TRACE_INFO("%u: set card_insert to %s\r\n", ci->num,
	cardins->card_insert ? "INSERTED" : "REMOVED");
	if (cardins->card_insert)
	PIO_Set(&ci->pin_insert);
	else
	PIO_Clear(&ci->pin_insert);
	usb_buf_free(msg);
	break;
	case SIMTRACE_MSGT_BD_CEMU_STATUS:
	card_emu_report_status(ci->ch);
	usb_buf_free(msg);
	break;
	case SIMTRACE_MSGT_BD_CEMU_STATS:
	default:
	/* FIXME: Send Error */
	usb_buf_free(msg);
	break;
	}
	}

	#ifdef PINS_PERST
	#include "wwan_perst.h"
	#endif

	static int usb_command_modem_reset(struct msgb msg, struct cardem_inst ci)
	{
	struct st_modem_reset mr = (struct st_modem_reset ) msg->l2h;

	if (msgb_l2len(msg) < sizeof(*mr))
	return -1;

	switch (mr->asserted) {
	#ifdef PINS_PERST
	case 0:
	wwan_perst_set(ci->num, 0);
	break;
	case 1:
	wwan_perst_set(ci->num, 1);
	break;
	case 2:
	wwan_perst_do_reset_pulse(ci->num, mr->pulse_duration_msec);
	break;
	#endif
	default:
	return -1;
	}

	return 0;
	}

	static int usb_command_sim_select(struct msgb msg, struct cardem_inst ci)
	{
	struct st_modem_sim_select mss = (struct st_modem_sim_select ) msg->l2h;

	if (msgb_l2len(msg) < sizeof(*mss))
	return -1;

	if (mss->remote_sim)
	sim_switch_use_physical(ci->num, 0);
	else
	sim_switch_use_physical(ci->num, 1);

	return 0;
	}

	/* handle a single USB command as received from the USB host */
	static void dispatch_usb_command_modem(struct msgb msg, struct cardem_inst ci)
	{
	struct simtrace_msg_hdr *hdr;

	hdr = (struct simtrace_msg_hdr *) msg->l1h;
	switch (hdr->msg_type) {
	case SIMTRACE_MSGT_DT_MODEM_RESET:
	usb_command_modem_reset(msg, ci);
	break;
	case SIMTRACE_MSGT_DT_MODEM_SIM_SELECT:
	usb_command_sim_select(msg, ci);
	break;
	case SIMTRACE_MSGT_BD_MODEM_STATUS:
	break;
	default:
	break;
	}
	usb_buf_free(msg);
	}

	/* handle a single USB command as received from the USB host */
	static void dispatch_usb_command(struct msgb msg, struct cardem_inst ci)
	{
	struct simtrace_msg_hdr sh = (struct simtrace_msg_hdr ) msg->l1h;

	if (msgb_length(msg) < sizeof(*sh)) {
	/* FIXME: Error */
	usb_buf_free(msg);
	return;
	}
	msg->l2h = msg->l1h + sizeof(*sh);

	switch (sh->msg_class) {
	case SIMTRACE_MSGC_GENERIC:
	dispatch_usb_command_generic(msg, ci);
	break;
	case SIMTRACE_MSGC_CARDEM:
	dispatch_usb_command_cardem(msg, ci);
	break;
	case SIMTRACE_MSGC_MODEM:
	/* FIXME: Find out why this fails if used for !=
	* MSGC_MODEM ?!? */
	dispatch_usb_command_modem(msg, ci);
	break;
	default:
	/* FIXME: Send Error */
	usb_buf_free(msg);
	break;
	}
	}

	static void dispatch_received_msg(struct msgb msg, struct cardem_inst ci)
	{
	struct msgb *segm;
	struct simtrace_msg_hdr *mh;

	/* check if we have multiple concatenated commands in
	* one message. USB endpoints are streams that don't
	* preserve the message boundaries */
	mh = (struct simtrace_msg_hdr *) msg->data;
	if (mh->msg_len == msgb_length(msg)) {
	/* fast path: only one message in buffer */
	dispatch_usb_command(msg, ci);
	return;
	}

	/* slow path: iterate over list of messages, allocating one new
	* reqe_ctx per segment */
	while (1) {
	mh = (struct simtrace_msg_hdr *) msg->data;

	segm = usb_buf_alloc(ci->ep_out);
	if (!segm) {
	TRACE_ERROR("%u: ENOMEM during msg segmentation\r\n",
	ci->num);
	break;
	}

	if (mh->msg_len > msgb_length(msg)) {
	TRACE_ERROR("%u: Unexpected large message (%u bytes)\n",
	ci->num, mh->msg_len);
	usb_buf_free(segm);
	} else {
	uint8_t *cur = msgb_put(segm, mh->msg_len);
	segm->l1h = segm->head;
	memcpy(cur, mh, mh->msg_len);
	dispatch_usb_command(segm, ci);
	}
	/* pull this message */
	msgb_pull(msg, mh->msg_len);
	/* abort if we're done */
	if (msgb_length(msg) <= 0)
	break;
	}

	usb_buf_free(msg);
	}

	/* iterate over the queue of incoming USB commands and dispatch/execute
	* them */
	static void process_any_usb_commands(struct llist_head *main_q,
	struct cardem_inst *ci)
	{
	struct llist_head *lh;
	struct msgb *msg;
	int i;

	/* limit the number of iterations to 10, to ensure we don't get
	* stuck here without returning to main loop processing */
	for (i = 0; i < 10; i++) {
	/* de-queue the list head in an irq-safe way */
	lh = llist_head_dequeue_irqsafe(main_q);
	if (!lh)
	break;
	msg = llist_entry(lh, struct msgb, list);
	dispatch_received_msg(msg, ci);
	}
	}

	/* main loop function, called repeatedly */
	void mode_cardemu_run(void)
	{
	struct llist_head *queue;
	unsigned int i;

	for (i = 0; i < ARRAY_SIZE(cardem_inst); i++) {
	struct cardem_inst *ci = &cardem_inst[i];

	/* drain the ring buffer from UART into card_emu */
	while (1) {
	__disable_irq();
	if (rbuf_is_empty(&ci->rb)) {
	__enable_irq();
	break;
	}
	uint8_t byte = rbuf_read(&ci->rb);
	__enable_irq();
	card_emu_process_rx_byte(ci->ch, byte);
	//TRACE_ERROR("%uRx%02x\r\n", i, byte);
	}

	/* first try to send any pending messages on IRQ */
	usb_refill_to_host(ci->ep_int);

	/* then try to send any pending messages on IN */
	usb_refill_to_host(ci->ep_in);

	/* ensure we can handle incoming USB messages from the
	* host */
	usb_refill_from_host(ci->ep_out);
	queue = usb_get_queue(ci->ep_out);
	process_any_usb_commands(queue, ci);
	}
	}