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authorJohannes Stezenbach <js@linuxtv.org>2005-05-16 21:54:10 -0700
committerLinus Torvalds <torvalds@ppc970.osdl.org>2005-05-17 07:59:24 -0700
commit2add87a95068d6457d4e5824d0417d39007665a4 (patch)
treef2aa0373421b0bd78ce900a41fa5a72b853e66de /drivers/media/dvb/b2c2/flexcop-reg.h
parent1ec359729960f7896db8f642454e603d22519d20 (diff)
[PATCH] dvb: b2c2/flexcop driver refactoring part 2: add modular Flexcop driver
b2c2/flexcop driver refactoring to support PCI and USB based cards part 2: add modular Flexcop driver Signed-off-by: Patrick Boettcher <pb@linuxtv.org> Signed-off-by: Johannes Stezenbach <js@linuxtv.org> Signed-off-by: Andrew Morton <akpm@osdl.org> Signed-off-by: Linus Torvalds <torvalds@osdl.org>
Diffstat (limited to 'drivers/media/dvb/b2c2/flexcop-reg.h')
-rw-r--r--drivers/media/dvb/b2c2/flexcop-reg.h700
1 files changed, 700 insertions, 0 deletions
diff --git a/drivers/media/dvb/b2c2/flexcop-reg.h b/drivers/media/dvb/b2c2/flexcop-reg.h
new file mode 100644
index 00000000000..41835c5280a
--- /dev/null
+++ b/drivers/media/dvb/b2c2/flexcop-reg.h
@@ -0,0 +1,700 @@
+/*
+ * This file is part of linux driver the digital TV devices equipped with B2C2 FlexcopII(b)/III
+ *
+ * flexcop-reg.h - register abstraction for FlexCopII, FlexCopIIb and FlexCopIII
+ *
+ * see flexcop.c for copyright information.
+ */
+#ifndef __FLEXCOP_REG_H__
+#define __FLEXCOP_REG_H__
+
+
+typedef enum {
+ FLEXCOP_UNK = 0,
+ FLEXCOP_II,
+ FLEXCOP_IIB,
+ FLEXCOP_III,
+} flexcop_revision_t;
+
+extern const char *flexcop_revision_names[];
+
+typedef enum {
+ FC_UNK = 0,
+ FC_AIR_DVB,
+ FC_AIR_ATSC,
+ FC_SKY,
+ FC_SKY_OLD,
+ FC_CABLE,
+} flexcop_device_type_t;
+
+typedef enum {
+ FC_USB = 0,
+ FC_PCI,
+} flexcop_bus_t;
+
+extern const char *flexcop_device_names[];
+
+/* FlexCop IBI Registers */
+
+/* flexcop_ibi_reg - a huge union representing the register structure */
+typedef union {
+ u32 raw;
+
+/* DMA 0x000 to 0x01c
+ * DMA1 0x000 to 0x00c
+ * DMA2 0x010 to 0x01c
+ */
+ struct {
+ u32 dma_0start : 1; /* set: data will be delivered to dma1_address0 */
+ u32 dma_0No_update : 1; /* set: dma1_cur_address will be updated, unset: no update */
+ u32 dma_address0 :30; /* physical/virtual host memory address0 DMA */
+ } dma_0x0;
+
+ struct {
+ u32 DMA_maxpackets : 8; /* (remapped) PCI DMA1 Packet Count Interrupt. This variable
+ is able to be read and written while bit(1) of register
+ 0x00c (remap_enable) is set. This variable represents
+ the number of packets that will be transmitted to the PCI
+ host using PCI DMA1 before an interrupt to the PCI is
+ asserted. This functionality may be enabled using bit(20)
+ of register 0x208. N=0 disables the IRQ. */
+ u32 dma_addr_size :24; /* size of memory buffer in DWORDs (bytesize / 4) for DMA */
+ } dma_0x4_remap;
+
+ struct {
+ u32 dma1timer : 7; /* reading PCI DMA1 timer ... when remap_enable is 0 */
+ u32 unused : 1;
+ u32 dma_addr_size :24;
+ } dma_0x4_read;
+
+ struct {
+ u32 unused : 1;
+ u32 dmatimer : 7; /* writing PCI DMA1 timer ... when remap_enable is 0 */
+ u32 dma_addr_size :24;
+ } dma_0x4_write;
+
+ struct {
+ u32 unused : 2;
+ u32 dma_cur_addr :30; /* current physical host memory address pointer for DMA */
+ } dma_0x8;
+
+ struct {
+ u32 dma_1start : 1; /* set: data will be delivered to dma_address1, when dma_address0 is full */
+ u32 remap_enable : 1; /* remap enable for 0x0x4(7:0) */
+ u32 dma_address1 :30; /* Physical/virtual address 1 on DMA */
+ } dma_0xc;
+
+/* Two-wire Serial Master and Clock 0x100-0x110 */
+ struct {
+// u32 slave_transmitter : 1; /* ???*/
+ u32 chipaddr : 7; /* two-line serial address of the target slave */
+ u32 reserved1 : 1;
+ u32 baseaddr : 8; /* address of the location of the read/write operation */
+ u32 data1_reg : 8; /* first byte in two-line serial read/write operation */
+ u32 working_start : 1; /* when doing a write operation this indicator is 0 when ready
+ * set to 1 when doing a write operation */
+ u32 twoWS_rw : 1; /* read/write indicator (1 = read, 0 write) */
+ u32 total_bytes : 2; /* number of data bytes in each two-line serial transaction (0 = 1 byte, 11 = 4byte)*/
+ u32 twoWS_port_reg : 2; /* port selection: 01 - Front End/Demod, 10 - EEPROM, 11 - Tuner */
+ u32 no_base_addr_ack_error : 1; /* writing: write-req: frame is produced w/o baseaddr, read-req: read-cycles w/o
+ * preceding address assignment write frame
+ * ACK_ERROR = 1 when no ACK from slave in the last transaction */
+ u32 st_done : 1; /* indicator for transaction is done */
+ } tw_sm_c_100;
+
+ struct {
+ u32 data2_reg : 8; /* 2nd data byte */
+ u32 data3_reg : 8; /* 3rd data byte */
+ u32 data4_reg : 8; /* 4th data byte */
+ u32 exlicit_stops : 1; /* when set, transactions are produced w/o trailing STOP flag, then send isolated STOP flags */
+ u32 force_stop : 1; /* isolated stop flag */
+ u32 unused : 6;
+ } tw_sm_c_104;
+
+/* Clock. The register allows the FCIII to convert an incoming Master clock
+ * (MCLK) signal into a lower frequency clock through the use of a LowCounter
+ * (TLO) and a High- Counter (THI). The time counts for THI and TLO are
+ * measured in MCLK; each count represents 4 MCLK input clock cycles.
+ *
+ * The default output for port #1 is set for Front End Demod communication. (0x108)
+ * The default output for port #2 is set for EEPROM communication. (0x10c)
+ * The default output for port #3 is set for Tuner communication. (0x110)
+ */
+ struct {
+ u32 thi1 : 6; /* Thi for port #1 (def: 100110b; 38) */
+ u32 reserved1 : 2;
+ u32 tlo1 : 5; /* Tlo for port #1 (def: 11100b; 28) */
+ u32 reserved2 :19;
+ } tw_sm_c_108;
+
+ struct {
+ u32 thi1 : 6; /* Thi for port #2 (def: 111001b; 57) */
+ u32 reserved1 : 2;
+ u32 tlo1 : 5; /* Tlo for port #2 (def: 11100b; 28) */
+ u32 reserved2 :19;
+ } tw_sm_c_10c;
+
+ struct {
+ u32 thi1 : 6; /* Thi for port #3 (def: 111001b; 57) */
+ u32 reserved1 : 2;
+ u32 tlo1 : 5; /* Tlo for port #3 (def: 11100b; 28) */
+ u32 reserved2 :19;
+ } tw_sm_c_110;
+
+/* LNB Switch Frequency 0x200
+ * Clock that creates the LNB switch tone. The default is set to have a fixed
+ * low output (not oscillating) to the LNB_CTL line.
+ */
+ struct {
+ u32 LNB_CTLHighCount_sig :15; /* It is the number of pre-scaled clock cycles that will be low. */
+ u32 LNB_CTLLowCount_sig :15; /* For example, to obtain a 22KHz output given a 45 Mhz Master
+ Clock signal (MCLK), set PreScalar=01 and LowCounter value to 0x1ff. */
+ u32 LNB_CTLPrescaler_sig : 2; /* pre-scaler divides MCLK: 00 (no division), 01 by 2, 10 by 4, 11 by 12 */
+ } lnb_switch_freq_200;
+
+/* ACPI, Peripheral Reset, LNB Polarity
+ * ACPI power conservation mode, LNB polarity selection (low or high voltage),
+ * and peripheral reset.
+ */
+ struct {
+ u32 ACPI1_sig : 1; /* turn of the power of tuner and LNB, not implemented in FCIII */
+ u32 ACPI3_sig : 1; /* turn of power of the complete satelite receiver board (except FCIII) */
+ u32 LNB_L_H_sig : 1; /* low or high voltage for LNB. (0 = low, 1 = high) */
+ u32 Per_reset_sig : 1; /* misc. init reset (default: 1), to reset set to low and back to high */
+ u32 reserved :20;
+ u32 Rev_N_sig_revision_hi : 4;/* 0xc in case of FCIII */
+ u32 Rev_N_sig_reserved1 : 2;
+ u32 Rev_N_sig_caps : 1; /* if 1, FCIII has 32 PID- and MAC-filters and is capable of IP multicast */
+ u32 Rev_N_sig_reserved2 : 1;
+ } misc_204;
+
+/* Control and Status 0x208 to 0x21c */
+/* Gross enable and disable control */
+ struct {
+ u32 Stream1_filter_sig : 1; /* Stream1 PID filtering */
+ u32 Stream2_filter_sig : 1; /* Stream2 PID filtering */
+ u32 PCR_filter_sig : 1; /* PCR PID filter */
+ u32 PMT_filter_sig : 1; /* PMT PID filter */
+
+ u32 EMM_filter_sig : 1; /* EMM PID filter */
+ u32 ECM_filter_sig : 1; /* ECM PID filter */
+ u32 Null_filter_sig : 1; /* Filters null packets, PID=0x1fff. */
+ u32 Mask_filter_sig : 1; /* mask PID filter */
+
+ u32 WAN_Enable_sig : 1; /* WAN output line through V8 memory space is activated. */
+ u32 WAN_CA_Enable_sig : 1; /* not in FCIII */
+ u32 CA_Enable_sig : 1; /* not in FCIII */
+ u32 SMC_Enable_sig : 1; /* CI stream data (CAI) goes directly to the smart card intf (opposed IBI 0x600 or SC-cmd buf). */
+
+ u32 Per_CA_Enable_sig : 1; /* not in FCIII */
+ u32 Multi2_Enable_sig : 1; /* ? */
+ u32 MAC_filter_Mode_sig : 1; /* (MAC_filter_enable) Globally enables MAC filters for Net PID filteres. */
+ u32 Rcv_Data_sig : 1; /* PID filtering module enable. When this bit is a one, the PID filter will
+ examine and process packets according to all other (individual) PID
+ filtering controls. If it a zero, no packet processing of any kind will
+ take place. All data from the tuner will be thrown away. */
+
+ u32 DMA1_IRQ_Enable_sig : 1; /* When set, a DWORD counter is enabled on PCI DMA1 that asserts the PCI
+ * interrupt after the specified count for filling the buffer. */
+ u32 DMA1_Timer_Enable_sig : 1; /* When set, a timer is enabled on PCI DMA1 that asserts the PCI interrupt
+ after a specified amount of time. */
+ u32 DMA2_IRQ_Enable_sig : 1; /* same as DMA1_IRQ_Enable_sig but for DMA2 */
+ u32 DMA2_Timer_Enable_sig : 1; /* same as DMA1_Timer_Enable_sig but for DMA2 */
+
+ u32 DMA1_Size_IRQ_Enable_sig : 1; /* When set, a packet count detector is enabled on PCI DMA1 that asserts the PCI interrupt. */
+ u32 DMA2_Size_IRQ_Enable_sig : 1; /* When set, a packet count detector is enabled on PCI DMA2 that asserts the PCI interrupt. */
+ u32 Mailbox_from_V8_Enable_sig: 1; /* When set, writes to the mailbox register produce an interrupt to the
+ PCI host to indicate that mailbox data is available. */
+
+ u32 unused : 9;
+ } ctrl_208;
+
+/* General status. When a PCI interrupt occurs, this register is read to
+ * discover the reason for the interrupt.
+ */
+ struct {
+ u32 DMA1_IRQ_Status : 1; /* When set(1) the DMA1 counter had generated an IRQ. Read Only. */
+ u32 DMA1_Timer_Status : 1; /* When set(1) the DMA1 timer had generated an IRQ. Read Only. */
+ u32 DMA2_IRQ_Status : 1; /* When set(1) the DMA2 counter had generated an IRQ. Read Only. */
+ u32 DMA2_Timer_Status : 1; /* When set(1) the DMA2 timer had generated an IRQ. Read Only. */
+ u32 DMA1_Size_IRQ_Status : 1; /* (Read only). This register is read after an interrupt to */
+ u32 DMA2_Size_IRQ_Status : 1; /* find out why we had an IRQ. Reading this register will clear this bit. Packet count*/
+ u32 Mailbox_from_V8_Status_sig: 1; /* Same as above. Reading this register will clear this bit. */
+ u32 Data_receiver_error : 1; /* 1 indicate an error in the receiver Front End (Tuner module) */
+ u32 Continuity_error_flag : 1; /* 1 indicates a continuity error in the TS stream. */
+ u32 LLC_SNAP_FLAG_set : 1; /* 1 indicates that the LCC_SNAP_FLAG was set. */
+ u32 Transport_Error : 1; /* When set indicates that an unexpected packet was received. */
+ u32 reserved :21;
+ } irq_20c;
+
+
+/* Software reset register */
+ struct {
+ u32 reset_blocks : 8; /* Enabled when Block_reset_enable = 0xB2 and 0x208 bits 15:8 = 0x00.
+ Each bit location represents a 0x100 block of registers. Writing
+ a one in a bit location resets that block of registers and the logic
+ that it controls. */
+ u32 Block_reset_enable : 8; /* This variable is set to 0xB2 when the register is written. */
+ u32 Special_controls :16; /* Asserts Reset_V8 => 0xC258; Turns on pci encryption => 0xC25A;
+ Turns off pci encryption => 0xC259 Note: pci_encryption default
+ at power-up is ON. */
+ } sw_reset_210;
+
+ struct {
+ u32 vuart_oe_sig : 1; /* When clear, the V8 processor has sole control of the serial UART
+ (RS-232 Smart Card interface). When set, the IBI interface
+ defined by register 0x600 controls the serial UART. */
+ u32 v2WS_oe_sig : 1; /* When clear, the V8 processor has direct control of the Two-line
+ Serial Master EEPROM target. When set, the Two-line Serial Master
+ EEPROM target interface is controlled by IBI register 0x100. */
+ u32 halt_V8_sig : 1; /* When set, contiguous wait states are applied to the V8-space
+ bus masters. Once this signal is cleared, normal V8-space
+ operations resume. */
+ u32 section_pkg_enable_sig: 1; /* When set, this signal enables the front end translation circuitry
+ to process section packed transport streams. */
+ u32 s2p_sel_sig : 1; /* Serial to parallel conversion. When set, polarized transport data
+ within the FlexCop3 front end circuitry is converted from a serial
+ stream into parallel data before downstream processing otherwise
+ interprets the data. */
+ u32 unused1 : 3;
+ u32 polarity_PS_CLK_sig: 1; /* This signal is used to invert the input polarity of the tranport
+ stream CLOCK signal before any processing occurs on the transport
+ stream within FlexCop3. */
+ u32 polarity_PS_VALID_sig: 1; /* This signal is used to invert the input polarity of the tranport
+ stream VALID signal before any processing occurs on the transport
+ stream within FlexCop3. */
+ u32 polarity_PS_SYNC_sig: 1; /* This signal is used to invert the input polarity of the tranport
+ stream SYNC signal before any processing occurs on the transport
+ stream within FlexCop3. */
+ u32 polarity_PS_ERR_sig: 1; /* This signal is used to invert the input polarity of the tranport
+ stream ERROR signal before any processing occurs on the transport
+ stream within FlexCop3. */
+ u32 unused2 :20;
+ } misc_214;
+
+/* Mailbox from V8 to host */
+ struct {
+ u32 Mailbox_from_V8 :32; /* When this register is written by either the V8 processor or by an
+ end host, an interrupt is generated to the PCI host to indicate
+ that mailbox data is available. Reading register 20c will clear
+ the IRQ. */
+ } mbox_v8_to_host_218;
+
+/* Mailbox from host to v8 Mailbox_to_V8
+ * Mailbox_to_V8 mailbox storage register
+ * used to send messages from PCI to V8. Writing to this register will send an
+ * IRQ to the V8. Then it can read the data from here. Reading this register
+ * will clear the IRQ. If the V8 is halted and bit 31 of this register is set,
+ * then this register is used instead as a direct interface to access the
+ * V8space memory.
+ */
+ struct {
+ u32 sysramaccess_data : 8; /* Data byte written or read from the specified address in V8 SysRAM. */
+ u32 sysramaccess_addr :15; /* 15 bit address used to access V8 Sys-RAM. */
+ u32 unused : 7;
+ u32 sysramaccess_write: 1; /* Write flag used to latch data into the V8 SysRAM. */
+ u32 sysramaccess_busmuster: 1; /* Setting this bit when the V8 is halted at 0x214 Bit(2) allows
+ this IBI register interface to directly drive the V8-space memory. */
+ } mbox_host_to_v8_21c;
+
+
+/* PIDs, Translation Bit, SMC Filter Select 0x300 to 0x31c */
+ struct {
+ u32 Stream1_PID :13; /* Primary use is receiving Net data, so these 13 bits normally
+ hold the PID value for the desired network stream. */
+ u32 Stream1_trans : 1; /* When set, Net translation will take place for Net data ferried in TS packets. */
+ u32 MAC_Multicast_filter : 1; /* When clear, multicast MAC filtering is not allowed for Stream1 and PID_n filters. */
+ u32 debug_flag_pid_saved : 1;
+ u32 Stream2_PID :13; /* 13 bits for Stream 2 PID filter value. General use. */
+ u32 Stream2_trans : 1; /* When set Tables/CAI translation will take place for the data ferried in
+ Stream2_PID TS packets. */
+ u32 debug_flag_write_status00 : 1;
+ u32 debug_fifo_problem : 1;
+ } pid_filter_300;
+
+ struct {
+ u32 PCR_PID :13; /* PCR stream PID filter value. Primary use is Program Clock Reference stream filtering. */
+ u32 PCR_trans : 1; /* When set, Tables/CAI translation will take place for these packets. */
+ u32 debug_overrun3 : 1;
+ u32 debug_overrun2 : 1;
+ u32 PMT_PID :13; /* stream PID filter value. Primary use is Program Management Table segment filtering. */
+ u32 PMT_trans : 1; /* When set, Tables/CAI translation will take place for these packets. */
+ u32 reserved : 2;
+ } pid_filter_304;
+
+ struct {
+ u32 EMM_PID :13; /* EMM PID filter value. Primary use is Entitlement Management Messaging for
+ conditional access-related data. */
+ u32 EMM_trans : 1; /* When set, Tables/CAI translation will take place for these packets. */
+ u32 EMM_filter_4 : 1; /* When set will pass only EMM data possessing the same ID code as the
+ first four bytes (32 bits) of the end-user s 6-byte Smart Card ID number Select */
+ u32 EMM_filter_6 : 1; /* When set will pass only EMM data possessing the same 6-byte code as the end-users
+ complete 6-byte Smart Card ID number. */
+ u32 ECM_PID :13; /* ECM PID filter value. Primary use is Entitlement Control Messaging for conditional
+ access-related data. */
+ u32 ECM_trans : 1; /* When set, Tables/CAI translation will take place for these packets. */
+ u32 reserved : 2;
+ } pid_filter_308;
+
+ struct {
+ u32 Group_PID :13; /* PID value for group filtering. */
+ u32 Group_trans : 1; /* When set, Tables/CAI translation will take place for these packets. */
+ u32 unused1 : 2;
+ u32 Group_mask :13; /* Mask value used in logical "and" equation that defines group filtering */
+ u32 unused2 : 3;
+ } pid_filter_30c_ext_ind_0_7;
+
+ struct {
+ u32 net_master_read :17;
+ u32 unused :15;
+ } pid_filter_30c_ext_ind_1;
+
+ struct {
+ u32 net_master_write :17;
+ u32 unused :15;
+ } pid_filter_30c_ext_ind_2;
+
+ struct {
+ u32 next_net_master_write :17;
+ u32 unused :15;
+ } pid_filter_30c_ext_ind_3;
+
+ struct {
+ u32 unused1 : 1;
+ u32 state_write :10;
+ u32 reserved1 : 6; /* default: 000100 */
+ u32 stack_read :10;
+ u32 reserved2 : 5; /* default: 00100 */
+ } pid_filter_30c_ext_ind_4;
+
+ struct {
+ u32 stack_cnt :10;
+ u32 unused :22;
+ } pid_filter_30c_ext_ind_5;
+
+ struct {
+ u32 pid_fsm_save_reg0 : 2;
+ u32 pid_fsm_save_reg1 : 2;
+ u32 pid_fsm_save_reg2 : 2;
+ u32 pid_fsm_save_reg3 : 2;
+ u32 pid_fsm_save_reg4 : 2;
+ u32 pid_fsm_save_reg300 : 2;
+ u32 write_status1 : 2;
+ u32 write_status4 : 2;
+ u32 data_size_reg :12;
+ u32 unused : 4;
+ } pid_filter_30c_ext_ind_6;
+
+ struct {
+ u32 index_reg : 5; /* (Index pointer) Points at an internal PIDn register. A binary code
+ representing one of 32 internal PIDn registers as well as its
+ corresponding internal MAC_lown register. */
+ u32 extra_index_reg : 3; /* This vector is used to select between sets of debug signals routed to register 0x30c. */
+ u32 AB_select : 1; /* Used in conjunction with 0x31c. read/write to the MAC_highA or MAC_highB register
+ 0=MAC_highB register, 1=MAC_highA */
+ u32 pass_alltables : 1; /* 1=Net packets are not filtered against the Network Table ID found in register 0x400.
+ All types of networks (DVB, ATSC, ISDB) are passed. */
+ u32 unused :22;
+ } index_reg_310;
+
+ struct {
+ u32 PID :13; /* PID value */
+ u32 PID_trans : 1; /* translation will take place for packets filtered */
+ u32 PID_enable_bit : 1; /* When set this PID filter is enabled */
+ u32 reserved :17;
+ } pid_n_reg_314;
+
+ struct {
+ u32 A4_byte : 8;
+ u32 A5_byte : 8;
+ u32 A6_byte : 8;
+ u32 Enable_bit : 1; /* enabled (1) or disabled (1) */
+ u32 HighAB_bit : 1; /* use MAC_highA (1) or MAC_highB (0) as MSB */
+ u32 reserved : 6;
+ } mac_low_reg_318;
+
+ struct {
+ u32 A1_byte : 8;
+ u32 A2_byte : 8;
+ u32 A3_byte : 8;
+ u32 reserved : 8;
+ } mac_high_reg_31c;
+
+/* Table, SMCID,MACDestination Filters 0x400 to 0x41c */
+ struct {
+ u32 reserved :16;
+#define fc_data_Tag_ID_DVB 0x3e
+#define fc_data_Tag_ID_ATSC 0x3f
+#define fc_data_Tag_ID_IDSB 0x8b
+ u32 data_Tag_ID :16;
+ } data_tag_400;
+
+ struct {
+ u32 Card_IDbyte6 : 8;
+ u32 Card_IDbyte5 : 8;
+ u32 Card_IDbyte4 : 8;
+ u32 Card_IDbyte3 : 8;
+ } card_id_408;
+
+ struct {
+ u32 Card_IDbyte2 : 8;
+ u32 Card_IDbyte1 : 8;
+ } card_id_40c;
+
+ /* holding the unique mac address of the receiver which houses the FlexCopIII */
+ struct {
+ u32 MAC1 : 8;
+ u32 MAC2 : 8;
+ u32 MAC3 : 8;
+ u32 MAC6 : 8;
+ } mac_address_418;
+
+ struct {
+ u32 MAC7 : 8;
+ u32 MAC8 : 8;
+ u32 reserved : 16;
+ } mac_address_41c;
+
+ struct {
+ u32 transmitter_data_byte : 8;
+ u32 ReceiveDataReady : 1;
+ u32 ReceiveByteFrameError: 1;
+ u32 txbuffempty : 1;
+ u32 reserved :21;
+ } ci_600;
+
+ struct {
+ u32 pi_d : 8;
+ u32 pi_ha :20;
+ u32 pi_rw : 1;
+ u32 pi_component_reg : 3;
+ } pi_604;
+
+ struct {
+ u32 serialReset : 1;
+ u32 oncecycle_read : 1;
+ u32 Timer_Read_req : 1;
+ u32 Timer_Load_req : 1;
+ u32 timer_data : 7;
+ u32 unused : 1; /* ??? not mentioned in data book */
+ u32 Timer_addr : 5;
+ u32 reserved : 3;
+ u32 pcmcia_a_mod_pwr_n : 1;
+ u32 pcmcia_b_mod_pwr_n : 1;
+ u32 config_Done_stat : 1;
+ u32 config_Init_stat : 1;
+ u32 config_Prog_n : 1;
+ u32 config_wr_n : 1;
+ u32 config_cs_n : 1;
+ u32 config_cclk : 1;
+ u32 pi_CiMax_IRQ_n : 1;
+ u32 pi_timeout_status : 1;
+ u32 pi_wait_n : 1;
+ u32 pi_busy_n : 1;
+ } pi_608;
+
+ struct {
+ u32 PID :13;
+ u32 key_enable : 1;
+#define fc_key_code_default 0x1
+#define fc_key_code_even 0x2
+#define fc_key_code_odd 0x3
+ u32 key_code : 2;
+ u32 key_array_col : 3;
+ u32 key_array_row : 5;
+ u32 dvb_en : 1; /* 0=TS bypasses the Descrambler */
+ u32 rw_flag : 1;
+ u32 reserved : 6;
+ } dvb_reg_60c;
+
+/* SRAM and Output Destination 0x700 to 0x714 */
+ struct {
+ u32 sram_addr :15;
+ u32 sram_rw : 1; /* 0=write, 1=read */
+ u32 sram_data : 8;
+ u32 sc_xfer_bit : 1;
+ u32 reserved1 : 3;
+ u32 oe_pin_reg : 1;
+ u32 ce_pin_reg : 1;
+ u32 reserved2 : 1;
+ u32 start_sram_ibi : 1;
+ } sram_ctrl_reg_700;
+
+ struct {
+ u32 net_addr_read :16;
+ u32 net_addr_write :16;
+ } net_buf_reg_704;
+
+ struct {
+ u32 cai_read :11;
+ u32 reserved1 : 5;
+ u32 cai_write :11;
+ u32 reserved2 : 6;
+ u32 cai_cnt : 4;
+ } cai_buf_reg_708;
+
+ struct {
+ u32 cao_read :11;
+ u32 reserved1 : 5;
+ u32 cap_write :11;
+ u32 reserved2 : 6;
+ u32 cao_cnt : 4;
+ } cao_buf_reg_70c;
+
+ struct {
+ u32 media_read :11;
+ u32 reserved1 : 5;
+ u32 media_write :11;
+ u32 reserved2 : 6;
+ u32 media_cnt : 4;
+ } media_buf_reg_710;
+
+ struct {
+ u32 NET_Dest : 2;
+ u32 CAI_Dest : 2;
+ u32 CAO_Dest : 2;
+ u32 MEDIA_Dest : 2;
+ u32 net_ovflow_error : 1;
+ u32 media_ovflow_error : 1;
+ u32 cai_ovflow_error : 1;
+ u32 cao_ovflow_error : 1;
+ u32 ctrl_usb_wan : 1;
+ u32 ctrl_sramdma : 1;
+ u32 ctrl_maximumfill : 1;
+ u32 reserved :17;
+ } sram_dest_reg_714;
+
+ struct {
+ u32 net_cnt :12;
+ u32 reserved1 : 4;
+ u32 net_addr_read : 1;
+ u32 reserved2 : 3;
+ u32 net_addr_write : 1;
+ u32 reserved3 :11;
+ } net_buf_reg_718;
+
+ struct {
+ u32 wan_speed_sig : 2;
+ u32 reserved1 : 6;
+ u32 wan_wait_state : 8;
+ u32 sram_chip : 2;
+ u32 sram_memmap : 2;
+ u32 reserved2 : 4;
+ u32 wan_pkt_frame : 4;
+ u32 reserved3 : 4;
+ } wan_ctrl_reg_71c;
+} flexcop_ibi_value;
+
+extern flexcop_ibi_value ibi_zero;
+
+typedef enum {
+ FC_I2C_PORT_DEMOD = 1,
+ FC_I2C_PORT_EEPROM = 2,
+ FC_I2C_PORT_TUNER = 3,
+} flexcop_i2c_port_t;
+
+typedef enum {
+ FC_WRITE = 0,
+ FC_READ = 1,
+} flexcop_access_op_t;
+
+typedef enum {
+ FC_SRAM_DEST_NET = 1,
+ FC_SRAM_DEST_CAI = 2,
+ FC_SRAM_DEST_CAO = 4,
+ FC_SRAM_DEST_MEDIA = 8
+} flexcop_sram_dest_t;
+
+typedef enum {
+ FC_SRAM_DEST_TARGET_WAN_USB = 0,
+ FC_SRAM_DEST_TARGET_DMA1 = 1,
+ FC_SRAM_DEST_TARGET_DMA2 = 2,
+ FC_SRAM_DEST_TARGET_FC3_CA = 3
+} flexcop_sram_dest_target_t;
+
+typedef enum {
+ FC_SRAM_2_32KB = 0, /* 64KB */
+ FC_SRAM_1_32KB = 1, /* 32KB - default fow FCII */
+ FC_SRAM_1_128KB = 2, /* 128KB */
+ FC_SRAM_1_48KB = 3, /* 48KB - default for FCIII */
+} flexcop_sram_type_t;
+
+typedef enum {
+ FC_WAN_SPEED_4MBITS = 0,
+ FC_WAN_SPEED_8MBITS = 1,
+ FC_WAN_SPEED_12MBITS = 2,
+ FC_WAN_SPEED_16MBITS = 3,
+} flexcop_wan_speed_t;
+
+typedef enum {
+ FC_DMA_1 = 1,
+ FC_DMA_2 = 2,
+} flexcop_dma_index_t;
+
+typedef enum {
+ FC_DMA_SUBADDR_0 = 1,
+ FC_DMA_SUBADDR_1 = 2,
+} flexcop_dma_addr_index_t;
+
+/* names of the particular registers */
+typedef enum {
+ dma1_000 = 0x000,
+ dma1_004 = 0x004,
+ dma1_008 = 0x008,
+ dma1_00c = 0x00c,
+ dma2_010 = 0x010,
+ dma2_014 = 0x014,
+ dma2_018 = 0x018,
+ dma2_01c = 0x01c,
+
+ tw_sm_c_100 = 0x100,
+ tw_sm_c_104 = 0x104,
+ tw_sm_c_108 = 0x108,
+ tw_sm_c_10c = 0x10c,
+ tw_sm_c_110 = 0x110,
+
+ lnb_switch_freq_200 = 0x200,
+ misc_204 = 0x204,
+ ctrl_208 = 0x208,
+ irq_20c = 0x20c,
+ sw_reset_210 = 0x210,
+ misc_214 = 0x214,
+ mbox_v8_to_host_218 = 0x218,
+ mbox_host_to_v8_21c = 0x21c,
+
+ pid_filter_300 = 0x300,
+ pid_filter_304 = 0x304,
+ pid_filter_308 = 0x308,
+ pid_filter_30c = 0x30c,
+ index_reg_310 = 0x310,
+ pid_n_reg_314 = 0x314,
+ mac_low_reg_318 = 0x318,
+ mac_high_reg_31c = 0x31c,
+
+ data_tag_400 = 0x400,
+ card_id_408 = 0x408,
+ card_id_40c = 0x40c,
+ mac_address_418 = 0x418,
+ mac_address_41c = 0x41c,
+
+ ci_600 = 0x600,
+ pi_604 = 0x604,
+ pi_608 = 0x608,
+ dvb_reg_60c = 0x60c,
+
+ sram_ctrl_reg_700 = 0x700,
+ net_buf_reg_704 = 0x704,
+ cai_buf_reg_708 = 0x708,
+ cao_buf_reg_70c = 0x70c,
+ media_buf_reg_710 = 0x710,
+ sram_dest_reg_714 = 0x714,
+ net_buf_reg_718 = 0x718,
+ wan_ctrl_reg_71c = 0x71c,
+} flexcop_ibi_register;
+
+#define flexcop_set_ibi_value(reg,attr,val) \
+ flexcop_ibi_value v = fc->read_ibi_reg(fc,reg); \
+ v.reg.attr = val; \
+ fc->write_ibi_reg(fc,reg,v); \
+
+#endif