nfc/libnfc-brcm.conf - device/htc/flounder - Git at Google

 ###############################################################################
 # Application options
 APPL_TRACE_LEVEL=0x01
 PROTOCOL_TRACE_LEVEL=0x00000000

 ###############################################################################
 # performance measurement
 # Change this setting to control how often USERIAL log the performance (throughput)
 # data on read/write/poll
 # defailt is to log performance dara for every 100 read or write
 #REPORT_PERFORMANCE_MEASURE=100

 ###############################################################################
 # File used for NFA storage
 NFA_STORAGE="/data/nfc"

 ###############################################################################
 # Insert a delay in milliseconds after NFC_WAKE and before write to NFCC
 NFC_WAKE_DELAY=20

 ###############################################################################
 # Various Delay settings (in ms) used in USERIAL
 #  POWER_ON_DELAY
 #    Delay after turning on chip, before writing to transport (default 300)
 #  PRE_POWER_OFF_DELAY
 #    Delay after deasserting NFC-Wake before turn off chip (default 0)
 #  POST_POWER_OFF_DELAY
 #    Delay after turning off chip, before USERIAL_close returns (default 0)
 #
 POWER_ON_DELAY=50
 PRE_POWER_OFF_DELAY=10
 #POST_POWER_OFF_DELAY=0

 ###############################################################################
 # Maximum time (ms) to wait for RESET NTF after setting REG_PU to high
 # The default is 1000.
 NFCC_ENABLE_TIMEOUT=0

 ###############################################################################
 # Device Manager Config
 #
 #  If NFA_DM_CFG is not provided, stack default settings are
 #  used (see nfa_dm_cfg.c).  They are as follows:
 #       0 (FALSE)     Automatic NDEF detection when background polling
 #       0 (FALSE)     Automatic NDEF read when background polling
 #
 #NFA_DM_CFG={00:00}

 ###############################################################################
 # Default poll duration (in ms)
 #  The defualt is 500ms if not set (see nfc_target.h)
 #NFA_DM_DISC_DURATION_POLL=500

 ###############################################################################
 # Startup Vendor Specific Configuration (100 bytes maximum);
 #  byte[0] TLV total len = 0x5
 #  byte[1] NCI_MTS_CMD|NCI_GID_PROP = 0x2f
 #  byte[2] NCI_MSG_FRAME_LOG = 0x9
 #  byte[3] 2
 #  byte[4] 0=turn off RF frame logging; 1=turn on
 #  byte[5] 0=turn off SWP frame logging; 1=turn on
 #  NFA_DM_START_UP_VSC_CFG={05:2F:09:02:01:01}

 ###############################################################################
 # Configure the default Destination Gate used by HCI (the default is 4, which
 # is the ETSI loopback gate.
 #NFA_HCI_DEFAULT_DEST_GATE=0x04

 ###############################################################################
 # Override the stack default for NFA_EE_MAX_EE_SUPPORTED set in nfc_target.h.
 # The value is set to 3 by default as it assumes we will discover 0xF2,
 # 0xF3, and 0xF4. If a platform will exclude an SE, this value can be reduced
 # so that the stack will not wait any longer than necessary.  It can be set to
 # 0 to disable EE and HCI sub-systems (i.e. if there are no SE on the system).
 # Note, if set to 0, the ACTIVE_SE setting should also be set to 0.
 NFA_MAX_EE_SUPPORTED=0

 ###############################################################################
 # Configure the single default SE to use.  The default is to use the first
 # SE that is detected by the stack.  This value might be used when the phone
 # supports multiple SE (e.g. 0xF3 and 0xF4) but you want to force it to use
 # one of them (e.g. 0xF4).  This can be set to 0 if there are no SE on the
 # system in order to skip SE initialization.
 ACTIVE_SE=0

 ###############################################################################
 # Configure the NFC Extras to open and use a static pipe.  If the value is
 # not set or set to 0, then the default is use a dynamic pipe based on a
 # destination gate (see NFA_HCI_DEFAULT_DEST_GATE).  Note there is a value
 # for each UICC (where F3="UICC0" and F4="UICC1")
 #NFA_HCI_STATIC_PIPE_ID_F3=0x70
 #NFA_HCI_STATIC_PIPE_ID_F4=0x71

 ###############################################################################
 # When disconnecting from Oberthur secure element, perform a warm-reset of
 # the secure element to deselect the applet.
 # The default hex value of the command is 0x3.  If this variable is undefined,
 # then this feature is not used.
 OBERTHUR_WARM_RESET_COMMAND=0x03

 ###############################################################################
 # Force UICC to only listen to the following technology(s).
 # The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
 # Default is NFA_TECHNOLOGY_MASK_A | NFA_TECHNOLOGY_MASK_B.
 #UICC_LISTEN_TECH_MASK=0x01

 ###############################################################################
 # AID for Empty Select command
 # If specified, this AID will be substituted when an Empty SELECT command is
 # detected.  The first byte is the length of the AID.  Maximum length is 16.
 AID_FOR_EMPTY_SELECT={08:A0:00:00:01:51:00:00:00}

 ###############################################################################
 # Force tag polling for the following technology(s).
 # The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
 # Default is NFA_TECHNOLOGY_MASK_A | NFA_TECHNOLOGY_MASK_B |
 #            NFA_TECHNOLOGY_MASK_F | NFA_TECHNOLOGY_MASK_ISO15693 |
 #            NFA_TECHNOLOGY_MASK_B_PRIME | NFA_TECHNOLOGY_MASK_A_ACTIVE |
 #            NFA_TECHNOLOGY_MASK_F_ACTIVE.
 #
 # Notable bits:
 #   NFA_TECHNOLOGY_MASK_A         0x01
 #   NFA_TECHNOLOGY_MASK_B         0x02
 #   NFA_TECHNOLOGY_MASK_F         0x04
 #   NFA_TECHNOLOGY_MASK_ISO15693  0x08
 #   NFA_TECHNOLOGY_MASK_B_PRIME   0x10
 #   NFA_TECHNOLOGY_MASK_KOVIO	    0x20
 #   NFA_TECHNOLOGY_MASK_A_ACTIVE    0x40
 #   NFA_TECHNOLOGY_MASK_F_ACTIVE    0x80
 POLLING_TECH_MASK=0xEF

 ###############################################################################
 # Force P2P to only listen for the following technology(s).
 # The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
 # Default is NFA_TECHNOLOGY_MASK_A | NFA_TECHNOLOGY_MASK_F |
 #            NFA_TECHNOLOGY_MASK_A_ACTIVE | NFA_TECHNOLOGY_MASK_F_ACTIVE
 #P2P_LISTEN_TECH_MASK=0xC5

 ###############################################################################
 # Maximum Number of Credits to be allowed by the NFCC
 #   This value overrides what the NFCC specifices allowing the host to have
 #   the control to work-around transport limitations.  If this value does
 #   not exist or is set to 0, the NFCC will provide the number of credits.
 #MAX_RF_DATA_CREDITS=1

 ###############################################################################
 # When screen is turned off, specify the desired power state of the controller.
 # 0: power-off-sleep state; DEFAULT
 # 1: full-power state (note: this is still low-power ("snooze") on BRCM devices.
 # 2: screen-off card-emulation (CE4/CE3/CE1 modes are used)
 SCREEN_OFF_POWER_STATE=1

 ###############################################################################
 # SPD Debug mode
 #  If set to 1, any failure of downloading a patch will trigger a hard-stop
 #SPD_DEBUG=0

 ###############################################################################
 # SPD Max Retry Count
 #  The number of attempts to download a patch before giving up (defualt is 3).
 #  Note, this resets after a power-cycle.
 #SPD_MAX_RETRY_COUNT=3

 ###############################################################################
 # transport driver
 #
 # TRANSPORT_DRIVER=<driver>
 #
 #  where <driver> can be, for example:
 #    "/dev/ttyS"        (UART)
 #    "/dev/bcmi2cnfc"   (I2C)
 #    "hwtun"            (HW Tunnel)
 #    "/dev/bcmspinfc"   (SPI)
 #    "/dev/btusb0"      (BT USB)
 TRANSPORT_DRIVER="/dev/bcm2079x"

 ###############################################################################
 # power control driver
 # Specify a kernel driver that support ioctl commands to control NFC_EN and
 # NFC_WAKE gpio signals.
 #
 # POWER_CONTRL_DRIVER=<driver>
 #  where <driver> can be, for example:
 #    "/dev/nfcpower"
 #    "/dev/bcmi2cnfc"   (I2C)
 #    "/dev/bcmspinfc"   (SPI)
 #    i2c and spi driver may be used to control NFC_EN and NFC_WAKE signal
 POWER_CONTROL_DRIVER="/dev/bcm2079x"

 ###############################################################################
 # I2C transport driver options
 # BCMI2CNFC_ADDRESS=0

 ###############################################################################
 # I2C transport driver try to read multiple packets in read() if data is available
 # remove the comment below to enable this feature
 #READ_MULTIPLE_PACKETS=1

 ###############################################################################
 # SPI transport driver options
 #SPI_NEGOTIATION={0A:F0:00:01:00:00:00:FF:FF:00:00}

 ###############################################################################
 # UART transport driver options
 #
 # PORT=1,2,3,...
 # BAUD=115200, 19200, 9600, 4800,
 # DATABITS=8, 7, 6, 5
 # PARITY="even" | "odd" | "none"
 # STOPBITS="0" | "1" | "1.5" | "2"

 #UART_PORT=2
 #UART_BAUD=115200
 #UART_DATABITS=8
 #UART_PARITY="none"
 #UART_STOPBITS="1"

 ###############################################################################
 # Insert a delay in microseconds per byte after a write to NFCC.
 # after writing a block of data to the NFCC, delay this an amopunt of time before
 # writing next block of data.  the delay is calculated as below
 #   NFC_WRITE_DELAY * (number of byte written) / 1000 milliseconds
 # e.g. after 259 bytes is written, delay (259 * 20 / 1000) 5 ms before next write
 NFC_WRITE_DELAY=20

 ###############################################################################
 # Configuration for the RF discovery frequency for each technology. The values mean
 # frequency for NFC Technology A
 #                   Technology B
 #                   Technology F
 #                   Proprietary Technology/15693
 #                   Proprietary Technology/B-Prime
 #                   Proprietary Technology/Kovio
 #                   Technology A active mode
 #                   Technology F active mode
 #POLL_FREQUENCY={01:01:01:01:01:01:01:01}

 ###############################################################################
 # Choose the presence-check algorithm for type-4 tag.  If not defined,
 # the default value is 1.
 # 0  NFA_RW_PRES_CHK_DEFAULT; Let stack selects an algorithm
 # 1  NFA_RW_PRES_CHK_I_BLOCK; ISO-DEP protocol's empty I-block
 # 2  NFA_RW_PRES_CHK_RESET; Deactivate to Sleep, then re-activate
 # 3  NFA_RW_PRES_CHK_RB_CH0; Type-4 tag protocol's ReadBinary command on channel 0
 # 4  NFA_RW_PRES_CHK_RB_CH3; Type-4 tag protocol's ReadBinary command on channel 3
 PRESENCE_CHECK_ALGORITHM=1
	###############################################################################
	# Application options
	APPL_TRACE_LEVEL=0x01
	PROTOCOL_TRACE_LEVEL=0x00000000

	###############################################################################
	# performance measurement
	# Change this setting to control how often USERIAL log the performance (throughput)
	# data on read/write/poll
	# defailt is to log performance dara for every 100 read or write
	#REPORT_PERFORMANCE_MEASURE=100

	###############################################################################
	# File used for NFA storage
	NFA_STORAGE="/data/nfc"

	###############################################################################
	# Insert a delay in milliseconds after NFC_WAKE and before write to NFCC
	NFC_WAKE_DELAY=20

	###############################################################################
	# Various Delay settings (in ms) used in USERIAL
	# POWER_ON_DELAY
	# Delay after turning on chip, before writing to transport (default 300)
	# PRE_POWER_OFF_DELAY
	# Delay after deasserting NFC-Wake before turn off chip (default 0)
	# POST_POWER_OFF_DELAY
	# Delay after turning off chip, before USERIAL_close returns (default 0)
	#
	POWER_ON_DELAY=50
	PRE_POWER_OFF_DELAY=10
	#POST_POWER_OFF_DELAY=0

	###############################################################################
	# Maximum time (ms) to wait for RESET NTF after setting REG_PU to high
	# The default is 1000.
	NFCC_ENABLE_TIMEOUT=0

	###############################################################################
	# Device Manager Config
	#
	# If NFA_DM_CFG is not provided, stack default settings are
	# used (see nfa_dm_cfg.c). They are as follows:
	# 0 (FALSE) Automatic NDEF detection when background polling
	# 0 (FALSE) Automatic NDEF read when background polling
	#
	#NFA_DM_CFG={00:00}

	###############################################################################
	# Default poll duration (in ms)
	# The defualt is 500ms if not set (see nfc_target.h)
	#NFA_DM_DISC_DURATION_POLL=500

	###############################################################################
	# Startup Vendor Specific Configuration (100 bytes maximum);
	# byte[0] TLV total len = 0x5
	# byte[1] NCI_MTS_CMD\|NCI_GID_PROP = 0x2f
	# byte[2] NCI_MSG_FRAME_LOG = 0x9
	# byte[3] 2
	# byte[4] 0=turn off RF frame logging; 1=turn on
	# byte[5] 0=turn off SWP frame logging; 1=turn on
	# NFA_DM_START_UP_VSC_CFG={05:2F:09:02:01:01}

	###############################################################################
	# Configure the default Destination Gate used by HCI (the default is 4, which
	# is the ETSI loopback gate.
	#NFA_HCI_DEFAULT_DEST_GATE=0x04

	###############################################################################
	# Override the stack default for NFA_EE_MAX_EE_SUPPORTED set in nfc_target.h.
	# The value is set to 3 by default as it assumes we will discover 0xF2,
	# 0xF3, and 0xF4. If a platform will exclude an SE, this value can be reduced
	# so that the stack will not wait any longer than necessary. It can be set to
	# 0 to disable EE and HCI sub-systems (i.e. if there are no SE on the system).
	# Note, if set to 0, the ACTIVE_SE setting should also be set to 0.
	NFA_MAX_EE_SUPPORTED=0

	###############################################################################
	# Configure the single default SE to use. The default is to use the first
	# SE that is detected by the stack. This value might be used when the phone
	# supports multiple SE (e.g. 0xF3 and 0xF4) but you want to force it to use
	# one of them (e.g. 0xF4). This can be set to 0 if there are no SE on the
	# system in order to skip SE initialization.
	ACTIVE_SE=0

	###############################################################################
	# Configure the NFC Extras to open and use a static pipe. If the value is
	# not set or set to 0, then the default is use a dynamic pipe based on a
	# destination gate (see NFA_HCI_DEFAULT_DEST_GATE). Note there is a value
	# for each UICC (where F3="UICC0" and F4="UICC1")
	#NFA_HCI_STATIC_PIPE_ID_F3=0x70
	#NFA_HCI_STATIC_PIPE_ID_F4=0x71

	###############################################################################
	# When disconnecting from Oberthur secure element, perform a warm-reset of
	# the secure element to deselect the applet.
	# The default hex value of the command is 0x3. If this variable is undefined,
	# then this feature is not used.
	OBERTHUR_WARM_RESET_COMMAND=0x03

	###############################################################################
	# Force UICC to only listen to the following technology(s).
	# The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
	# Default is NFA_TECHNOLOGY_MASK_A \| NFA_TECHNOLOGY_MASK_B.
	#UICC_LISTEN_TECH_MASK=0x01

	###############################################################################
	# AID for Empty Select command
	# If specified, this AID will be substituted when an Empty SELECT command is
	# detected. The first byte is the length of the AID. Maximum length is 16.
	AID_FOR_EMPTY_SELECT={08:A0:00:00:01:51:00:00:00}

	###############################################################################
	# Force tag polling for the following technology(s).
	# The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
	# Default is NFA_TECHNOLOGY_MASK_A \| NFA_TECHNOLOGY_MASK_B \|
	# NFA_TECHNOLOGY_MASK_F \| NFA_TECHNOLOGY_MASK_ISO15693 \|
	# NFA_TECHNOLOGY_MASK_B_PRIME \| NFA_TECHNOLOGY_MASK_A_ACTIVE \|
	# NFA_TECHNOLOGY_MASK_F_ACTIVE.
	#
	# Notable bits:
	# NFA_TECHNOLOGY_MASK_A 0x01
	# NFA_TECHNOLOGY_MASK_B 0x02
	# NFA_TECHNOLOGY_MASK_F 0x04
	# NFA_TECHNOLOGY_MASK_ISO15693 0x08
	# NFA_TECHNOLOGY_MASK_B_PRIME 0x10
	# NFA_TECHNOLOGY_MASK_KOVIO 0x20
	# NFA_TECHNOLOGY_MASK_A_ACTIVE 0x40
	# NFA_TECHNOLOGY_MASK_F_ACTIVE 0x80
	POLLING_TECH_MASK=0xEF

	###############################################################################
	# Force P2P to only listen for the following technology(s).
	# The bits are defined as tNFA_TECHNOLOGY_MASK in nfa_api.h.
	# Default is NFA_TECHNOLOGY_MASK_A \| NFA_TECHNOLOGY_MASK_F \|
	# NFA_TECHNOLOGY_MASK_A_ACTIVE \| NFA_TECHNOLOGY_MASK_F_ACTIVE
	#P2P_LISTEN_TECH_MASK=0xC5

	###############################################################################
	# Maximum Number of Credits to be allowed by the NFCC
	# This value overrides what the NFCC specifices allowing the host to have
	# the control to work-around transport limitations. If this value does
	# not exist or is set to 0, the NFCC will provide the number of credits.
	#MAX_RF_DATA_CREDITS=1

	###############################################################################
	# When screen is turned off, specify the desired power state of the controller.
	# 0: power-off-sleep state; DEFAULT
	# 1: full-power state (note: this is still low-power ("snooze") on BRCM devices.
	# 2: screen-off card-emulation (CE4/CE3/CE1 modes are used)
	SCREEN_OFF_POWER_STATE=1

	###############################################################################
	# SPD Debug mode
	# If set to 1, any failure of downloading a patch will trigger a hard-stop
	#SPD_DEBUG=0

	###############################################################################
	# SPD Max Retry Count
	# The number of attempts to download a patch before giving up (defualt is 3).
	# Note, this resets after a power-cycle.
	#SPD_MAX_RETRY_COUNT=3

	###############################################################################
	# transport driver
	#
	# TRANSPORT_DRIVER=<driver>
	#
	# where <driver> can be, for example:
	# "/dev/ttyS" (UART)
	# "/dev/bcmi2cnfc" (I2C)
	# "hwtun" (HW Tunnel)
	# "/dev/bcmspinfc" (SPI)
	# "/dev/btusb0" (BT USB)
	TRANSPORT_DRIVER="/dev/bcm2079x"

	###############################################################################
	# power control driver
	# Specify a kernel driver that support ioctl commands to control NFC_EN and
	# NFC_WAKE gpio signals.
	#
	# POWER_CONTRL_DRIVER=<driver>
	# where <driver> can be, for example:
	# "/dev/nfcpower"
	# "/dev/bcmi2cnfc" (I2C)
	# "/dev/bcmspinfc" (SPI)
	# i2c and spi driver may be used to control NFC_EN and NFC_WAKE signal
	POWER_CONTROL_DRIVER="/dev/bcm2079x"

	###############################################################################
	# I2C transport driver options
	# BCMI2CNFC_ADDRESS=0

	###############################################################################
	# I2C transport driver try to read multiple packets in read() if data is available
	# remove the comment below to enable this feature
	#READ_MULTIPLE_PACKETS=1

	###############################################################################
	# SPI transport driver options
	#SPI_NEGOTIATION={0A:F0:00:01:00:00:00:FF:FF:00:00}

	###############################################################################
	# UART transport driver options
	#
	# PORT=1,2,3,...
	# BAUD=115200, 19200, 9600, 4800,
	# DATABITS=8, 7, 6, 5
	# PARITY="even" \| "odd" \| "none"
	# STOPBITS="0" \| "1" \| "1.5" \| "2"

	#UART_PORT=2
	#UART_BAUD=115200
	#UART_DATABITS=8
	#UART_PARITY="none"
	#UART_STOPBITS="1"

	###############################################################################
	# Insert a delay in microseconds per byte after a write to NFCC.
	# after writing a block of data to the NFCC, delay this an amopunt of time before
	# writing next block of data. the delay is calculated as below
	# NFC_WRITE_DELAY * (number of byte written) / 1000 milliseconds
	# e.g. after 259 bytes is written, delay (259 * 20 / 1000) 5 ms before next write
	NFC_WRITE_DELAY=20

	###############################################################################
	# Configuration for the RF discovery frequency for each technology. The values mean
	# frequency for NFC Technology A
	# Technology B
	# Technology F
	# Proprietary Technology/15693
	# Proprietary Technology/B-Prime
	# Proprietary Technology/Kovio
	# Technology A active mode
	# Technology F active mode
	#POLL_FREQUENCY={01:01:01:01:01:01:01:01}

	###############################################################################
	# Choose the presence-check algorithm for type-4 tag. If not defined,
	# the default value is 1.
	# 0 NFA_RW_PRES_CHK_DEFAULT; Let stack selects an algorithm
	# 1 NFA_RW_PRES_CHK_I_BLOCK; ISO-DEP protocol's empty I-block
	# 2 NFA_RW_PRES_CHK_RESET; Deactivate to Sleep, then re-activate
	# 3 NFA_RW_PRES_CHK_RB_CH0; Type-4 tag protocol's ReadBinary command on channel 0
	# 4 NFA_RW_PRES_CHK_RB_CH3; Type-4 tag protocol's ReadBinary command on channel 3
	PRESENCE_CHECK_ALGORITHM=1