/*
 * avrdude - A Downloader/Uploader for AVR device programmers
 * Copyright (C) Joerg Wunsch
 *
 * 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, see <http://www.gnu.org/licenses/>.
 */

/* $Id$ */

#ifndef libavrdude_h
#define libavrdude_h

#include <stdio.h>
#include <limits.h>
#include <stdbool.h>
#include <stdint.h>

typedef uint32_t pinmask_t;
/*
 * Values returned by library functions.
 * Some library functions also return a count, i.e. a positive
 * number greater than 0.
 */
#define LIBAVRDUDE_SUCCESS 0
#define LIBAVRDUDE_GENERAL_FAILURE (-1)
#define LIBAVRDUDE_NOTSUPPORTED (-2) // operation not supported
#define LIBAVRDUDE_SOFTFAIL (-3) // returned by avr_signature() if caller
                                 // might proceed with chip erase

/* formerly lists.h */

/*----------------------------------------------------------------------
  General purpose linked list routines - header file declarations.

  Author : Brian Dean
  Date   : 10 January, 1990
  ----------------------------------------------------------------------*/

typedef void * LISTID;
typedef void * LNODEID;


/*----------------------------------------------------------------------
  several defines to access the LIST structure as as stack or a queue
  --- use for program readability
  ----------------------------------------------------------------------*/
#define STACKID LISTID
#define SNODEID LNODEID
#define QUEUEID LISTID
#define QNODEID LNODEID


#define PUSH(s,d)    lins_n(s,d,1)   /* push 'd' onto the stack */
#define POP(s)       lrmv_n(s,1)     /* pop the stack */
#define LOOKSTACK(s) lget_n(s,1)     /* look at the top of the stack, 
					but don't pop */


#define ENQUEUE(q,d) lins_n(q,d,1)   /* put 'd' on the end of the queue */
#define DEQUEUE(q)   lrmv(q)         /* remove next item from the front of 
					the queue */
#define REQUEUE(q,d) ladd(q,d)       /* re-insert (push) item back on the
					front of the queue */
#define LOOKQUEUE(q) lget(q)         /* return next item on the queue, 
					but don't dequeue */
#define QUEUELEN(q)  lsize(q)       /* length of the queue */


#define LISTADD(l,d) ladd(l,d)       /* add to end of the list */
#define LISTRMV(l,d) lrmv_d(l,d)     /* remove from end of the list */


#ifdef __cplusplus
extern "C" {
#endif

/* .................... Function Prototypes .................... */

LISTID     lcreat      ( void * liststruct, int poolsize );
void       ldestroy    ( LISTID lid );
void       ldestroy_cb ( LISTID lid, void (*ucleanup)(void * data_ptr) );

LNODEID    lfirst ( LISTID  ); /* head of the list */
LNODEID    llast  ( LISTID  ); /* tail of the list */
LNODEID    lnext  ( LNODEID ); /* next item in the list */
LNODEID    lprev  ( LNODEID ); /* previous item in the list */
void     * ldata  ( LNODEID ); /* data at the current position */
int        lsize  ( LISTID  ); /* number of elements in the list */

int        ladd     ( LISTID lid, void * p );
int        laddo    ( LISTID lid, void *p, 
		      int (*compare)(const void *p1,const void *p2),
		      LNODEID * firstdup );
int        laddu    ( LISTID lid, void * p, 
		      int (*compare)(const void *p1,const void *p2));
int        lins_n   ( LISTID lid, void * d, unsigned int n );
int        lins_ln  ( LISTID lid, LNODEID lnid, void * data_ptr );

void     * lget    ( LISTID lid );
void     * lget_n  ( LISTID lid, unsigned int n );
LNODEID    lget_ln ( LISTID lid, unsigned int n );

void     * lrmv    ( LISTID lid );
void     * lrmv_n  ( LISTID lid, unsigned int n );
void     * lrmv_ln ( LISTID lid, LNODEID lnid );
void     * lrmv_d  ( LISTID lid, void * data_ptr );

LISTID     lcat    ( LISTID lid1, LISTID lid2 );

void       lsort   ( LISTID lid, int (*compare)(void * p1, void * p2));

void     * lsrch   ( LISTID lid, void * p, int (*compare)(void *p1,void *p2));

int        lprint  ( FILE * f, LISTID lid );

#ifdef __cplusplus
}
#endif

/* formerly avrpart.h */

/*
 * AVR serial programming instructions
 */
enum {
  AVR_OP_READ,
  AVR_OP_WRITE,
  AVR_OP_READ_LO,
  AVR_OP_READ_HI,
  AVR_OP_WRITE_LO,
  AVR_OP_WRITE_HI,
  AVR_OP_LOADPAGE_LO,
  AVR_OP_LOADPAGE_HI,
  AVR_OP_LOAD_EXT_ADDR,
  AVR_OP_WRITEPAGE,
  AVR_OP_CHIP_ERASE,
  AVR_OP_PGM_ENABLE,
  AVR_OP_MAX
};


enum {
  AVR_CMDBIT_IGNORE,  /* bit is ignored on input and output */
  AVR_CMDBIT_VALUE,   /* bit is set to 0 or 1 for input or output */
  AVR_CMDBIT_ADDRESS, /* this bit represents an input address bit */
  AVR_CMDBIT_INPUT,   /* this bit is an input bit */
  AVR_CMDBIT_OUTPUT   /* this bit is an output bit */
};

enum { /* these are assigned to reset_disposition of AVRPART */
  RESET_DEDICATED,    /* reset pin is dedicated */
  RESET_IO            /* reset pin might be configured as an I/O pin */
};

enum ctl_stack_t {
  CTL_STACK_NONE,     /* no control stack defined */
  CTL_STACK_PP,	      /* parallel programming control stack */
  CTL_STACK_HVSP      /* high voltage serial programming control stack */
};

/*
 * serial programming instruction bit specifications
 */
typedef struct cmdbit {
  int          type;  /* AVR_CMDBIT_* */
  int          bitno; /* which input bit to use for this command bit */
  int          value; /* bit value if type == AVR_CMDBIT_VALUD */
} CMDBIT;

typedef struct opcode {
  CMDBIT        bit[32]; /* opcode bit specs */
} OPCODE;


/* Any changes here, please also reflect in dev_part_strct() of developer_opts.c */
#define AVRPART_SERIALOK       0x0001  /* part supports serial programming */
#define AVRPART_PARALLELOK     0x0002  /* part supports parallel programming */
#define AVRPART_PSEUDOPARALLEL 0x0004  /* part has pseudo parallel support */
#define AVRPART_HAS_JTAG       0x0008  /* part has a JTAG i/f */
#define AVRPART_ALLOWFULLPAGEBITSTREAM 0x0010 /* JTAG ICE mkII param. */
#define AVRPART_ENABLEPAGEPROGRAMMING 0x0020 /* JTAG ICE mkII param. */
#define AVRPART_HAS_DW         0x0040  /* part has a debugWire i/f */
#define AVRPART_HAS_PDI        0x0080  /* part has PDI i/f rather than ISP (ATxmega) */
#define AVRPART_AVR32          0x0100  /* part is in AVR32 family */
#define AVRPART_INIT_SMC       0x0200  /* part will undergo chip erase */
#define AVRPART_WRITE          0x0400  /* at least one write operation specified */
#define AVRPART_HAS_TPI        0x0800  /* part has TPI i/f rather than ISP (ATtiny4/5/9/10) */
#define AVRPART_IS_AT90S1200   0x1000  /* part is an AT90S1200 (needs special treatment) */
#define AVRPART_HAS_UPDI       0x2000  /* part has UPDI i/f (AVR8X) */

#define HV_UPDI_VARIANT_0      0 /* Shared UPDI/GPIO/RESET pin, HV on UPDI pin (tinyAVR0/1/2)*/
#define HV_UPDI_VARIANT_1      1 /* Dedicated UPDI pin, no HV (megaAVR0/AVR-Dx) */
#define HV_UPDI_VARIANT_2      2 /* Shared UPDI pin, HV on _RESET (AVR-Ex) */

#define AVR_DESCLEN 64
#define AVR_IDLEN   32
#define AVR_FAMILYIDLEN 7
#define AVR_SIBLEN 16
#define CTL_STACK_SIZE 32
#define FLASH_INSTR_SIZE 3
#define EEPROM_INSTR_SIZE 20

#define TAG_ALLOCATED          1    /* memory byte is allocated */

/* Any changes here, please also reflect in dev_part_strct() of developer_opts.c */
typedef struct avrpart {
  char          desc[AVR_DESCLEN];  /* long part name */
  char          id[AVR_IDLEN];      /* short part name */
  char          family_id[AVR_FAMILYIDLEN+1]; /* family id in the SIB (avr8x) */
  int           hvupdi_variant;     /* HV pulse on UPDI pin, no pin or RESET pin */
  int           stk500_devcode;     /* stk500 device code */
  int           avr910_devcode;     /* avr910 device code */
  int           chip_erase_delay;   /* microseconds */
  unsigned char pagel;              /* for parallel programming */
  unsigned char bs2;                /* for parallel programming */
  unsigned char signature[3];       /* expected value of signature bytes */
  unsigned short usbpid;            /* USB DFU product ID (0 = none) */
  int           reset_disposition;  /* see RESET_ enums */
  int           retry_pulse;        /* retry program enable by pulsing
                                       this pin (PIN_AVR_*) */
  unsigned      flags;              /* see AVRPART_ masks */

  int           timeout;            /* stk500 v2 xml file parameter */
  int           stabdelay;          /* stk500 v2 xml file parameter */
  int           cmdexedelay;        /* stk500 v2 xml file parameter */
  int           synchloops;         /* stk500 v2 xml file parameter */
  int           bytedelay;          /* stk500 v2 xml file parameter */
  int           pollindex;          /* stk500 v2 xml file parameter */
  unsigned char pollvalue;          /* stk500 v2 xml file parameter */
  int           predelay;           /* stk500 v2 xml file parameter */
  int           postdelay;          /* stk500 v2 xml file parameter */
  int           pollmethod;         /* stk500 v2 xml file parameter */

  enum ctl_stack_t ctl_stack_type;  /* what to use the ctl stack for */
  unsigned char controlstack[CTL_STACK_SIZE]; /* stk500v2 PP/HVSP ctl stack */
  unsigned char flash_instr[FLASH_INSTR_SIZE]; /* flash instructions (debugWire, JTAG) */
  unsigned char eeprom_instr[EEPROM_INSTR_SIZE]; /* EEPROM instructions (debugWire, JTAG) */

  int           hventerstabdelay;   /* stk500 v2 hv mode parameter */
  int           progmodedelay;      /* stk500 v2 hv mode parameter */
  int           latchcycles;        /* stk500 v2 hv mode parameter */
  int           togglevtg;          /* stk500 v2 hv mode parameter */
  int           poweroffdelay;      /* stk500 v2 hv mode parameter */
  int           resetdelayms;       /* stk500 v2 hv mode parameter */
  int           resetdelayus;       /* stk500 v2 hv mode parameter */
  int           hvleavestabdelay;   /* stk500 v2 hv mode parameter */
  int           resetdelay;         /* stk500 v2 hv mode parameter */
  int           chiperasepulsewidth; /* stk500 v2 hv mode parameter */
  int           chiperasepolltimeout; /* stk500 v2 hv mode parameter */
  int           chiperasetime;      /* stk500 v2 hv mode parameter */
  int           programfusepulsewidth; /* stk500 v2 hv mode parameter */
  int           programfusepolltimeout; /* stk500 v2 hv mode parameter */
  int           programlockpulsewidth; /* stk500 v2 hv mode parameter */
  int           programlockpolltimeout; /* stk500 v2 hv mode parameter */
  int           synchcycles;        /* stk500 v2 hv mode parameter */
  int           hvspcmdexedelay;    /* stk500 v2 xml file parameter */

  unsigned char idr;                /* JTAG ICE mkII XML file parameter */
  unsigned char rampz;              /* JTAG ICE mkII XML file parameter */
  unsigned char spmcr;              /* JTAG ICE mkII XML file parameter */
  unsigned short eecr;              /* JTAC ICE mkII XML file parameter */
  unsigned int mcu_base;            /* Base address of MCU control block in ATxmega devices */
  unsigned int nvm_base;            /* Base address of NVM controller in ATxmega devices */
  unsigned int ocd_base;            /* Base address of OCD module in AVR8X/UPDI devices */
  int           ocdrev;             /* OCD revision (JTAGICE3 parameter, from AS6 XML files) */

  OPCODE      * op[AVR_OP_MAX];     /* opcodes */

  LISTID        mem;                /* avr memory definitions */
  LISTID        mem_alias;          /* memory alias definitions */
  char          *config_file;       /* config file where defined */
  int           lineno;             /* config file line number */
} AVRPART;

#define AVR_MEMDESCLEN 64
typedef struct avrmem {
  char desc[AVR_MEMDESCLEN];  /* memory description ("flash", "eeprom", etc) */
  int paged;                  /* page addressed (e.g. ATmega flash) */
  int size;                   /* total memory size in bytes */
  int page_size;              /* size of memory page (if page addressed) */
  int num_pages;              /* number of pages (if page addressed) */
  unsigned int offset;        /* offset in IO memory (ATxmega) */
  int min_write_delay;        /* microseconds */
  int max_write_delay;        /* microseconds */
  int pwroff_after_write;     /* after this memory type is written to,
                                 the device must be powered off and
                                 back on, see errata
                                 http://www.atmel.com/dyn/resources/prod_documents/doc1280.pdf */
  unsigned char readback[2];  /* polled read-back values */

  int mode;                   /* stk500 v2 xml file parameter */
  int delay;                  /* stk500 v2 xml file parameter */
  int blocksize;              /* stk500 v2 xml file parameter */
  int readsize;               /* stk500 v2 xml file parameter */
  int pollindex;              /* stk500 v2 xml file parameter */

  unsigned char * buf;        /* pointer to memory buffer */
  unsigned char * tags;       /* allocation tags */
  OPCODE * op[AVR_OP_MAX];    /* opcodes */
} AVRMEM;

typedef struct avrmem_alias {
  char desc[AVR_MEMDESCLEN];  /* alias name ("syscfg0" etc.) */
  AVRMEM *aliased_mem;
} AVRMEM_ALIAS;

#ifdef __cplusplus
extern "C" {
#endif

/* Functions for OPCODE structures */
OPCODE * avr_new_opcode(void);
void     avr_free_opcode(OPCODE * op);
int avr_set_bits(OPCODE * op, unsigned char * cmd);
int avr_set_addr(OPCODE * op, unsigned char * cmd, unsigned long addr);
int avr_set_input(OPCODE * op, unsigned char * cmd, unsigned char data);
int avr_get_output(OPCODE * op, unsigned char * res, unsigned char * data);
int avr_get_output_index(OPCODE * op);

/* Functions for AVRMEM structures */
AVRMEM * avr_new_memtype(void);
AVRMEM_ALIAS * avr_new_memalias(void);
int avr_initmem(AVRPART * p);
AVRMEM * avr_dup_mem(AVRMEM * m);
void     avr_free_mem(AVRMEM * m);
void     avr_free_memalias(AVRMEM_ALIAS * m);
AVRMEM * avr_locate_mem(AVRPART * p, const char * desc);
AVRMEM * avr_locate_mem_noalias(AVRPART * p, const char * desc);
AVRMEM_ALIAS * avr_locate_memalias(AVRPART * p, const char * desc);
AVRMEM_ALIAS * avr_find_memalias(AVRPART * p, AVRMEM * m_orig);
void avr_mem_display(const char * prefix, FILE * f, AVRMEM * m, AVRPART * p,
                     int type, int verbose);

/* Functions for AVRPART structures */
AVRPART * avr_new_part(void);
AVRPART * avr_dup_part(AVRPART * d);
void      avr_free_part(AVRPART * d);
AVRPART * locate_part(LISTID parts, const char * partdesc);
AVRPART * locate_part_by_avr910_devcode(LISTID parts, int devcode);
AVRPART * locate_part_by_signature(LISTID parts, unsigned char * sig,
                                   int sigsize);
void avr_display(FILE * f, AVRPART * p, const char * prefix, int verbose);

typedef void (*walk_avrparts_cb)(const char *name, const char *desc,
                                 const char *cfgname, int cfglineno,
                                 void *cookie);
void walk_avrparts(LISTID avrparts, walk_avrparts_cb cb, void *cookie);
void sort_avrparts(LISTID avrparts);

int compare_memory_masked(AVRMEM * m, uint8_t buf1, uint8_t buf2);

#ifdef __cplusplus
}
#endif

/* formerly pindefs.h */

enum {
  PPI_AVR_VCC = 1,
  PPI_AVR_BUFF,
  PIN_AVR_RESET,
  PIN_AVR_SCK,
  PIN_AVR_MOSI,
  PIN_AVR_MISO,
  PIN_LED_ERR,
  PIN_LED_RDY,
  PIN_LED_PGM,
  PIN_LED_VFY,
  N_PINS
};

#define PIN_MASK    (UINT_MAX>>1)
#define PIN_INVERSE (~(PIN_MASK))	/* flag for inverted pin in serbb */
#define PIN_MIN     0   /* smallest allowed pin number */
#define PIN_MAX     31  /* largest allowed pin number */

#ifdef HAVE_LINUXGPIO
/* Embedded systems might have a lot more gpio than only 0-31 */
#undef PIN_MAX
#define PIN_MAX     400 /* largest allowed pin number */
#endif

/** Number of pins in each element of the bitfield */
#define PIN_FIELD_ELEMENT_SIZE (sizeof(pinmask_t) * 8)
/** Numer of elements to store the complete bitfield of all pins */
#define PIN_FIELD_SIZE ((PIN_MAX + PIN_FIELD_ELEMENT_SIZE)/PIN_FIELD_ELEMENT_SIZE)

/**
 * This sets the corresponding bits to 1 or 0, the inverse mask is used to invert the value in necessary.
 * It uses only the lowest element (index=0) of the bitfield, which should be enough for most
 * programmers.
 *
 * @param[in] x       input value
 * @param[in] pgm     the programmer whose pin definitions to use
 * @param[in] pinname the logical name of the pin (PIN_AVR_*, ...)
 * @param[in] level   the logical level (level != 0 => 1, level == 0 => 0),
 *                      if the pin is defined as inverted the resulting bit is also inverted
 * @returns           the input value with the relevant bits modified
 */
#define SET_BITS_0(x,pgm,pinname,level) (((x) & ~(pgm)->pin[pinname].mask[0]) \
    | (\
        (pgm)->pin[pinname].mask[0] & ( \
             (level) \
             ?~((pgm)->pin[pinname].inverse[0]) \
             : ((pgm)->pin[pinname].inverse[0]) \
        ) \
    ) \
)

/**
 * Check if the corresponding bit is set (returns != 0) or cleared.
 * The inverse mask is used, to invert the relevant bits.
 * If the pin definition contains multiple pins, then a single set pin leads to return value != 0.
 * Then you have to check the relevant bits of the returned value, if you need more information.
 * It uses only the lowest element (index=0) of the bitfield, which should be enough for most
 * programmers.
 *
 * @param[in] x       input value
 * @param[in] pgm     the programmer whose pin definitions to use
 * @param[in] pinname the logical name of the pin (PIN_AVR_*, ...)
 * @returns           the input value with only the relevant bits (which are already inverted,
 *                      so you get always the logical level)
 */
#define GET_BITS_0(x,pgm,pinname)       (((x) ^ (pgm)->pin[pinname].inverse[0]) & (pgm)->pin[pinname].mask[0])

/**
 * Data structure to hold used pins by logical function (PIN_AVR_*, ...)
 */
struct pindef_t {
  pinmask_t mask[PIN_FIELD_SIZE]; ///< bitfield of used pins
  pinmask_t inverse[PIN_FIELD_SIZE]; ///< bitfield of inverse/normal usage of used pins
};

/**
 * Data structure to define a checklist of valid pins for each function.
 */
struct pin_checklist_t {
  int pinname; ///< logical pinname eg. PIN_AVR_SCK
  int mandatory; ///< is this a mandatory pin
  const struct pindef_t* valid_pins; ///< mask defines allowed pins, inverse define is they might be used inverted
};

/**
 * Adds a pin in the pin definition as normal or inverse pin.
 *
 * @param[out] pindef pin definition to update
 * @param[in] pin number of pin [0..PIN_MAX]
 * @param[in] inverse inverse (true) or normal (false) pin
 */
void pin_set_value(struct pindef_t * const pindef, const int pin, const bool inverse);

/**
 * Clear all defined pins in pindef.
 *
 * @param[out] pindef pin definition to clear
 */
void pin_clear_all(struct pindef_t * const pindef);

struct programmer_t; /* forward declaration */

/**
 * Convert for given programmer new pin definitions to old pin definitions.
 *
 * @param[inout] pgm programmer whose pins shall be converted.
 */
int pgm_fill_old_pins(struct programmer_t * const pgm);

/**
 * This function checks all pin of pgm against the constraints given in the checklist.
 * It checks if 
 * @li any invalid pins are used
 * @li valid pins are used inverted when not allowed
 * @li any pins are used by more than one function
 * @li any mandatory pin is not set all.
 *
 * In case of any error it report the wrong function and the pin numbers.
 * For verbose >= 2 it also reports the possible correct values.
 * For verbose >=3 it shows also which pins were ok.
 *
 * @param[in] pgm the programmer to check
 * @param[in] checklist the constraint for the pins
 * @param[in] size the number of entries in checklist
 * @param[in] output false suppresses error messages to the user
 * @returns 0 if all pin definitions are valid, -1 otherwise
 */
int pins_check(const struct programmer_t * const pgm, const struct pin_checklist_t * const checklist, const int size, const bool output);

/**
 * Returns the name of the pin as string.
 * 
 * @param pinname the pinname which we want as string.
 * @returns a string with the pinname, or <unknown> if pinname is invalid.
 */
const char * avr_pin_name(int pinname);

/**
 * This function returns a string representation of defined pins eg. ~1,2,~4,~5,7
 * Another execution of this function will overwrite the previous result in the static buffer.
 *
 * @param[in] pindef the pin definition for which we want the string representation
 * @returns pointer to a static string.
 */
const char * pins_to_str(const struct pindef_t * const pindef);

/**
 * This function returns a string representation of pins in the mask eg. 1,3,5-7,9,12
 * Another execution of this function will overwrite the previous result in the static buffer.
 * Consecutive pin number are representated as start-end.
 *
 * @param[in] pinmask the pin mask for which we want the string representation
 * @returns pointer to a static string.
 */
const char * pinmask_to_str(const pinmask_t * const pinmask);

/* formerly serial.h */

/* This is the API for the generic serial interface. The implementations are
   actually provided by the target dependant files:

   ser_posix.c : posix serial interface.
   ser_win32.c : native win32 serial interface.

   The target file will be selected at configure time. */

extern long serial_recv_timeout;
union filedescriptor
{
  int ifd;
  void *pfd;
  struct
  {
    void *handle;
    int rep;                    /* bulk read endpoint */
    int wep;                    /* bulk write endpoint */
    int eep;                    /* event read endpoint */
    int max_xfer;               /* max transfer size */
    int use_interrupt_xfer;     /* device uses interrupt transfers */
  } usb;
};

#define SERIAL_CS5          0x0000
#define SERIAL_CS6          0x0001
#define SERIAL_CS7          0x0002
#define SERIAL_CS8          0x0004

#define SERIAL_NO_CSTOPB    0x0000
#define SERIAL_CSTOPB       0x0008

#define SERIAL_NO_CREAD     0x0000
#define SERIAL_CREAD        0x0010

#define SERIAL_NO_PARITY    0x0000
#define SERIAL_PARENB       0x0020
#define SERIAL_PARODD       0x0040

#define SERIAL_NO_CLOCAL    0x0000
#define SERIAL_CLOCAL       0x0080

#define SERIAL_8N1 (SERIAL_CS8 | SERIAL_NO_CSTOPB | SERIAL_CREAD | SERIAL_NO_PARITY | SERIAL_CLOCAL)
#define SERIAL_8E1 (SERIAL_CS8 | SERIAL_NO_CSTOPB | SERIAL_CREAD | SERIAL_PARENB    | SERIAL_CLOCAL)
#define SERIAL_8E2 (SERIAL_CS8 | SERIAL_CSTOPB    | SERIAL_CREAD | SERIAL_PARENB    | SERIAL_CLOCAL)

union pinfo
{
  struct {
    long baud;
    unsigned long cflags;
  } serialinfo;
  struct
  {
    unsigned short vid;
    unsigned short pid;
    unsigned short flags;
#define PINFO_FL_USEHID         0x0001
#define PINFO_FL_SILENT         0x0002  /* don't complain if not found */
  } usbinfo;
};


struct serial_device
{
  // open should return -1 on error, other values on success
  int (*open)(char * port, union pinfo pinfo, union filedescriptor *fd); 
  int (*setparams)(union filedescriptor *fd, long baud, unsigned long cflags);
  void (*close)(union filedescriptor *fd);

  int (*send)(union filedescriptor *fd, const unsigned char * buf, size_t buflen);
  int (*recv)(union filedescriptor *fd, unsigned char * buf, size_t buflen);
  int (*drain)(union filedescriptor *fd, int display);

  int (*set_dtr_rts)(union filedescriptor *fd, int is_on);

  int flags;
#define SERDEV_FL_NONE         0x0000 /* no flags */
#define SERDEV_FL_CANSETSPEED  0x0001 /* device can change speed */
};

extern struct serial_device *serdev;
extern struct serial_device serial_serdev;
extern struct serial_device usb_serdev;
extern struct serial_device usb_serdev_frame;
extern struct serial_device avrdoper_serdev;
extern struct serial_device usbhid_serdev;

#define serial_open (serdev->open)
#define serial_setparams (serdev->setparams)
#define serial_close (serdev->close)
#define serial_send (serdev->send)
#define serial_recv (serdev->recv)
#define serial_drain (serdev->drain)
#define serial_set_dtr_rts (serdev->set_dtr_rts)

/* formerly pgm.h */

#define ON  1
#define OFF 0

#define PGM_DESCLEN 80
#define PGM_PORTLEN PATH_MAX
#define PGM_TYPELEN 32
#define PGM_USBSTRINGLEN 256

typedef enum {
  EXIT_VCC_UNSPEC,
  EXIT_VCC_ENABLED,
  EXIT_VCC_DISABLED
} exit_vcc_t;

typedef enum {
  EXIT_RESET_UNSPEC,
  EXIT_RESET_ENABLED,
  EXIT_RESET_DISABLED
} exit_reset_t;

typedef enum {
  EXIT_DATAHIGH_UNSPEC,
  EXIT_DATAHIGH_ENABLED,
  EXIT_DATAHIGH_DISABLED
} exit_datahigh_t;

typedef enum {
  CONNTYPE_PARALLEL,
  CONNTYPE_SERIAL,
  CONNTYPE_USB,
  CONNTYPE_SPI
} conntype_t;

typedef struct programmer_t {
  LISTID id;
  char desc[PGM_DESCLEN];
  char type[PGM_TYPELEN];
  char port[PGM_PORTLEN];
  void (*initpgm)(struct programmer_t * pgm);
  unsigned int pinno[N_PINS];
  struct pindef_t pin[N_PINS];
  exit_vcc_t exit_vcc;
  exit_reset_t exit_reset;
  exit_datahigh_t exit_datahigh;
  conntype_t conntype;
  int ppidata;
  int ppictrl;
  int baudrate;
  int usbvid;
  LISTID usbpid;
  char usbdev[PGM_USBSTRINGLEN], usbsn[PGM_USBSTRINGLEN];
  char usbvendor[PGM_USBSTRINGLEN], usbproduct[PGM_USBSTRINGLEN];
  double bitclock;    /* JTAG ICE clock period in microseconds */
  int ispdelay;    /* ISP clock delay */
  union filedescriptor fd;
  int  page_size;  /* page size if the programmer supports paged write/load */
  int  (*rdy_led)        (struct programmer_t * pgm, int value);
  int  (*err_led)        (struct programmer_t * pgm, int value);
  int  (*pgm_led)        (struct programmer_t * pgm, int value);
  int  (*vfy_led)        (struct programmer_t * pgm, int value);
  int  (*initialize)     (struct programmer_t * pgm, AVRPART * p);
  void (*display)        (struct programmer_t * pgm, const char * p);
  void (*enable)         (struct programmer_t * pgm);
  void (*disable)        (struct programmer_t * pgm);
  void (*powerup)        (struct programmer_t * pgm);
  void (*powerdown)      (struct programmer_t * pgm);
  int  (*program_enable) (struct programmer_t * pgm, AVRPART * p);
  int  (*chip_erase)     (struct programmer_t * pgm, AVRPART * p);
  int  (*unlock)         (struct programmer_t * pgm, AVRPART * p);
  int  (*cmd)            (struct programmer_t * pgm, const unsigned char *cmd,
                          unsigned char *res);
  int  (*cmd_tpi)        (struct programmer_t * pgm, const unsigned char *cmd,
                          int cmd_len, unsigned char res[], int res_len);
  int  (*spi)            (struct programmer_t * pgm, const unsigned char *cmd,
                          unsigned char *res, int count);
  int  (*open)           (struct programmer_t * pgm, char * port);
  void (*close)          (struct programmer_t * pgm);
  int  (*paged_write)    (struct programmer_t * pgm, AVRPART * p, AVRMEM * m, 
                          unsigned int page_size, unsigned int baseaddr,
                          unsigned int n_bytes);
  int  (*paged_load)     (struct programmer_t * pgm, AVRPART * p, AVRMEM * m,
                          unsigned int page_size, unsigned int baseaddr,
                          unsigned int n_bytes);
  int  (*page_erase)     (struct programmer_t * pgm, AVRPART * p, AVRMEM * m,
                          unsigned int baseaddr);
  void (*write_setup)    (struct programmer_t * pgm, AVRPART * p, AVRMEM * m);
  int  (*write_byte)     (struct programmer_t * pgm, AVRPART * p, AVRMEM * m,
                          unsigned long addr, unsigned char value);
  int  (*read_byte)      (struct programmer_t * pgm, AVRPART * p, AVRMEM * m,
                          unsigned long addr, unsigned char * value);
  int  (*read_sig_bytes) (struct programmer_t * pgm, AVRPART * p, AVRMEM * m);
  int  (*read_sib)       (struct programmer_t * pgm, AVRPART * p, char *sib);
  void (*print_parms)    (struct programmer_t * pgm);
  int  (*set_vtarget)    (struct programmer_t * pgm, double v);
  int  (*set_varef)      (struct programmer_t * pgm, unsigned int chan, double v);
  int  (*set_fosc)       (struct programmer_t * pgm, double v);
  int  (*set_sck_period) (struct programmer_t * pgm, double v);
  int  (*setpin)         (struct programmer_t * pgm, int pinfunc, int value);
  int  (*getpin)         (struct programmer_t * pgm, int pinfunc);
  int  (*highpulsepin)   (struct programmer_t * pgm, int pinfunc);
  int  (*parseexitspecs) (struct programmer_t * pgm, char *s);
  int  (*perform_osccal) (struct programmer_t * pgm);
  int  (*parseextparams) (struct programmer_t * pgm, LISTID xparams);
  void (*setup)          (struct programmer_t * pgm);
  void (*teardown)       (struct programmer_t * pgm);
  char *config_file;          /* config file where defined */
  int  lineno;                /* config file line number */
  void *cookie;		      /* for private use by the programmer */
  char flag;		      /* for private use of the programmer */
  LISTID hvupdi_support;  /* List of UPDI HV variants the tool supports. See HV_UPDI_VARIANT_ */
} PROGRAMMER;

#ifdef __cplusplus
extern "C" {
#endif

PROGRAMMER * pgm_new(void);
PROGRAMMER * pgm_dup(const PROGRAMMER * const src);
void         pgm_free(PROGRAMMER * const p);

void programmer_display(PROGRAMMER * pgm, const char * p);

/* show is a mask like this (1<<PIN_AVR_SCK)|(1<<PIN_AVR_MOSI)| ... */
#define SHOW_ALL_PINS (~0u)
#define SHOW_PPI_PINS ((1<<PPI_AVR_VCC)|(1<<PPI_AVR_BUFF))
#define SHOW_AVR_PINS ((1<<PIN_AVR_RESET)|(1<<PIN_AVR_SCK)|(1<<PIN_AVR_MOSI)|(1<<PIN_AVR_MISO))
#define SHOW_LED_PINS ((1<<PIN_LED_ERR)|(1<<PIN_LED_RDY)|(1<<PIN_LED_PGM)|(1<<PIN_LED_VFY))
void pgm_display_generic_mask(PROGRAMMER * pgm, const char * p, unsigned int show);
void pgm_display_generic(PROGRAMMER * pgm, const char * p);

PROGRAMMER * locate_programmer(LISTID programmers, const char * configid);

typedef void (*walk_programmers_cb)(const char *name, const char *desc,
                                    const char *cfgname, int cfglineno,
                                    void *cookie);
void walk_programmers(LISTID programmers, walk_programmers_cb cb, void *cookie);

void sort_programmers(LISTID programmers);

#ifdef __cplusplus
}
#endif

/* formerly avr.h */

typedef void (*FP_UpdateProgress)(int percent, double etime, char *hdr);

extern struct avrpart parts[];

extern FP_UpdateProgress update_progress;

#ifdef __cplusplus
extern "C" {
#endif

int avr_tpi_poll_nvmbsy(PROGRAMMER *pgm);
int avr_tpi_chip_erase(PROGRAMMER * pgm, AVRPART * p);
int avr_tpi_program_enable(PROGRAMMER * pgm, AVRPART * p, unsigned char guard_time);
int avr_read_byte_default(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem,
			  unsigned long addr, unsigned char * value);

int avr_read(PROGRAMMER * pgm, AVRPART * p, char * memtype, AVRPART * v);

int avr_write_page(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem,
                   unsigned long addr);

int avr_write_byte(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem,
                   unsigned long addr, unsigned char data);

int avr_write_byte_default(PROGRAMMER * pgm, AVRPART * p, AVRMEM * mem,
			   unsigned long addr, unsigned char data);

int avr_write(PROGRAMMER * pgm, AVRPART * p, char * memtype, int size,
              int auto_erase);

int avr_signature(PROGRAMMER * pgm, AVRPART * p);

int avr_verify(AVRPART * p, AVRPART * v, char * memtype, int size);

int avr_get_cycle_count(PROGRAMMER * pgm, AVRPART * p, int * cycles);

int avr_put_cycle_count(PROGRAMMER * pgm, AVRPART * p, int cycles);

#define disable_trailing_ff_removal() avr_mem_hiaddr(NULL)
int avr_mem_hiaddr(AVRMEM * mem);

int avr_chip_erase(PROGRAMMER * pgm, AVRPART * p);

int avr_unlock(PROGRAMMER * pgm, AVRPART * p);

void report_progress (int completed, int total, char *hdr);

#ifdef __cplusplus
}
#endif

/* formerly fileio.h */

typedef enum {
  FMT_AUTO,
  FMT_SREC,
  FMT_IHEX,
  FMT_RBIN,
  FMT_IMM,
  FMT_HEX,
  FMT_DEC,
  FMT_OCT,
  FMT_BIN,
  FMT_ELF
} FILEFMT;

struct fioparms {
  int    op;
  char * mode;
  char * iodesc;
  char * dir;
  char * rw;
  unsigned int fileoffset;
};

enum {
  FIO_READ,
  FIO_WRITE,
  FIO_READ_FOR_VERIFY,
};

#ifdef __cplusplus
extern "C" {
#endif

char * fmtstr(FILEFMT format);

int fileio(int oprwv, char * filename, FILEFMT format,
           struct avrpart * p, char * memtype, int size);

#ifdef __cplusplus
}
#endif


/* formerly update.h */

enum {
  DEVICE_READ,
  DEVICE_WRITE,
  DEVICE_VERIFY
};

enum updateflags {
  UF_NONE = 0,
  UF_NOWRITE = 1,
  UF_AUTO_ERASE = 2,
};


typedef struct update_t {
  char * memtype;
  int    op;
  char * filename;
  int    format;
} UPDATE;

#ifdef __cplusplus
extern "C" {
#endif

extern UPDATE * parse_op(char * s);
extern UPDATE * dup_update(UPDATE * upd);
extern UPDATE * new_update(int op, char * memtype, int filefmt,
			   char * filename);
extern void free_update(UPDATE * upd);
extern int do_op(PROGRAMMER * pgm, struct avrpart * p, UPDATE * upd,
		 enum updateflags flags);

#ifdef __cplusplus
}
#endif


/* formerly pgm_type.h */

/*LISTID programmer_types;*/

typedef struct programmer_type_t {
  const char * const id;
  void (*initpgm)(struct programmer_t * pgm);
  const char * const desc;
} PROGRAMMER_TYPE;

#ifdef __cplusplus
extern "C" {
#endif

const PROGRAMMER_TYPE * locate_programmer_type(/*LISTID programmer_types, */const char * id);

typedef void (*walk_programmer_types_cb)(const char *id, const char *desc,
                                    void *cookie);
void walk_programmer_types(/*LISTID programmer_types,*/ walk_programmer_types_cb cb, void *cookie);

#ifdef __cplusplus
}
#endif

/* formerly config.h */

extern LISTID       part_list;
extern LISTID       programmers;
extern char         default_programmer[];
extern char         default_parallel[];
extern char         default_serial[];
extern char         default_spi[];
extern double       default_bitclock;

/* This name is fixed, it's only here for symmetry with
 * default_parallel and default_serial. */
#define DEFAULT_USB "usb"

#ifdef __cplusplus
extern "C" {
#endif

int init_config(void);

void cleanup_config(void);

int read_config(const char * file);

#ifdef __cplusplus
}
#endif


/* formerly confwin.h */

#if defined(WIN32)

#ifdef __cplusplus
extern "C" {
#endif

void win_sys_config_set(char sys_config[PATH_MAX]);
void win_usr_config_set(char usr_config[PATH_MAX]);

#ifdef __cplusplus
}
#endif

#endif  /* WIN32 */


#endif  /* libavrdude_h */