#ifndef DIVE_H
#define DIVE_H

#include <stdlib.h>
#include <time.h>

#include <glib.h>
#include <libxml/tree.h>

/*
 * Some silly typedefs to make our units very explicit.
 *
 * Also, the units are chosen so that values can be expressible as
 * integers, so that we never have FP rounding issues. And they
 * are small enough that converting to/from imperial units doesn't
 * really matter.
 *
 * We also strive to make '0' a meaningless number saying "not
 * initialized", since many values are things that may not have
 * been reported (eg cylinder pressure or temperature from dive
 * computers that don't support them). But sometimes -1 is an even
 * more explicit way of saying "not there".
 *
 * Thus "millibar" for pressure, for example, or "millikelvin" for
 * temperatures. Doing temperatures in celsius or fahrenheit would
 * make for loss of precision when converting from one to the other,
 * and using millikelvin is SI-like but also means that a temperature
 * of '0' is clearly just a missing temperature or cylinder pressure.
 *
 * Also strive to use units that can not possibly be mistaken for a
 * valid value in a "normal" system without conversion. If the max
 * depth of a dive is '20000', you probably didn't convert from mm on
 * output, or if the max depth gets reported as "0.2ft" it was either
 * a really boring dive, or there was some missing input conversion,
 * and a 60-ft dive got recorded as 60mm.
 *
 * Doing these as "structs containing value" means that we always
 * have to explicitly write out those units in order to get at the
 * actual value. So there is hopefully little fear of using a value
 * in millikelvin as Fahrenheit by mistake.
 *
 * We don't actually use these all yet, so maybe they'll change, but
 * I made a number of types as guidelines.
 */
typedef struct {
	int seconds;
} duration_t;

typedef struct {
	int mm;
} depth_t;

typedef struct {
	int mbar;
} pressure_t;

typedef struct {
	int mkelvin;
} temperature_t;

typedef struct {
	int mliter;
} volume_t;

typedef struct {
	int permille;
} fraction_t;

typedef struct {
	int grams;
} weight_t;

struct gasmix {
	fraction_t o2;
	fraction_t he;
};

typedef struct {
	volume_t size;
	pressure_t workingpressure;
	const char *description;	/* "LP85", "AL72", "AL80", "HP100+" or whatever */
} cylinder_type_t;

typedef struct {
	cylinder_type_t type;
	struct gasmix gasmix;
	pressure_t start, end, sample_start, sample_end;
} cylinder_t;

extern int get_pressure_units(unsigned int mb, const char **units);
extern double get_depth_units(unsigned int mm, int *frac, const char **units);
extern double get_volume_units(unsigned int mm, int *frac, const char **units);
extern double get_temp_units(unsigned int mm, const char **units);

static inline double ml_to_cuft(int ml)
{
	return ml / 28316.8466;
}

static inline double cuft_to_l(double cuft)
{
	return cuft * 28.3168466;
}

static inline double mm_to_feet(int mm)
{
	return mm * 0.00328084;
}

static inline int to_feet(depth_t depth)
{
	return mm_to_feet(depth.mm) + 0.5;
}

static double mkelvin_to_C(int mkelvin)
{
	return (mkelvin - 273150) / 1000.0;
}

static double mkelvin_to_F(int mkelvin)
{
	return mkelvin * 9 / 5000.0 - 459.670;
}

static inline int to_C(temperature_t temp)
{
	if (!temp.mkelvin)
		return 0;
	return mkelvin_to_C(temp.mkelvin) + 0.5;
}

static inline int to_F(temperature_t temp)
{
	if (!temp.mkelvin)
		return 0;
	return mkelvin_to_F(temp.mkelvin) + 0.5;
}

static inline int to_K(temperature_t temp)
{
	if (!temp.mkelvin)
		return 0;
	return (temp.mkelvin + 499)/1000;
}

static inline double psi_to_bar(double psi)
{
	return psi / 14.5037738;
}
static inline int to_PSI(pressure_t pressure)
{
	return pressure.mbar * 0.0145037738 + 0.5;
}

static inline double bar_to_atm(double bar)
{
	return bar / 1.01325;
}

static inline double to_ATM(pressure_t pressure)
{
	return pressure.mbar / 1013.25;
}

static inline int mbar_to_PSI(int mbar)
{
	pressure_t p = {mbar};
	return to_PSI(p);
}

struct sample {
	duration_t time;
	depth_t depth;
	temperature_t temperature;
	pressure_t cylinderpressure;
	int cylinderindex;
};

/*
 * Events are currently pretty meaningless. This is
 * just based on the random data that libdivecomputer
 * gives us. I'm not sure what a real "architected"
 * event model would actually look like, but right
 * now you can associate a list of events with a dive,
 * and we'll do something about it.
 */
struct event {
	struct event *next;
	duration_t time;
	int type, flags, value;
	char name[];
};

#define MAX_CYLINDERS (8)

struct dive {
	int number;
	time_t when;
	char *location;
	char *notes;
	char *divemaster, *buddy;
	double latitude, longitude;
	depth_t maxdepth, meandepth;
	duration_t duration, surfacetime;
	depth_t visibility;
	temperature_t airtemp, watertemp;
	cylinder_t cylinder[MAX_CYLINDERS];
	int sac, otu;
	struct event *events;
	int samples, alloc_samples;
	struct sample sample[];
};

/*
 * We keep our internal data in well-specified units, but
 * the input and output may come in some random format. This
 * keeps track of those units.
 */
/* turns out in Win32 PASCAL is defined as a calling convention */
#ifdef WIN32
#undef PASCAL
#endif
struct units {
	enum { METERS, FEET } length;
	enum { LITER, CUFT } volume;
	enum { BAR, PSI, PASCAL } pressure;
	enum { CELSIUS, FAHRENHEIT, KELVIN } temperature;
	enum { KG, LBS } weight;
};

extern const struct units SI_units, IMPERIAL_units;
extern struct units input_units, output_units;

extern int verbose;

struct dive_table {
	int nr, allocated, preexisting;
	struct dive **dives;
};

extern struct dive_table dive_table;

extern int selected_dive;
#define current_dive (get_dive(selected_dive))

static inline struct dive *get_dive(unsigned int nr)
{
	if (nr >= dive_table.nr)
		return NULL;
	return dive_table.dives[nr];
}

extern void parse_xml_init(void);
extern void parse_xml_file(const char *filename, GError **error);
extern void set_filename(const char *filename);

#ifdef XSLT
extern xmlDoc *test_xslt_transforms(xmlDoc *doc);
#endif

extern void show_dive_info(struct dive *);
extern void flush_dive_info_changes(struct dive *);

extern void show_dive_equipment(struct dive *);
extern void flush_dive_equipment_changes(struct dive *);

extern void show_dive_stats(struct dive *);

extern void update_dive(struct dive *new_dive);
extern void save_dives(const char *filename);

static inline unsigned int dive_size(int samples)
{
	return sizeof(struct dive) + samples*sizeof(struct sample);
}

extern time_t utc_mktime(struct tm *tm);

extern struct dive *alloc_dive(void);
extern void record_dive(struct dive *dive);

extern struct sample *prepare_sample(struct dive **divep);
extern void finish_sample(struct dive *dive, struct sample *sample);

extern void report_dives(gboolean imported);
extern struct dive *fixup_dive(struct dive *dive);
extern struct dive *try_to_merge(struct dive *a, struct dive *b);

extern void renumber_dives(int nr);

extern void add_event(struct dive *dive, int time, int type, int flags, int value, const char *name);

/* UI related protopypes */

extern void init_ui(int *argcp, char ***argvp);

extern void run_ui(void);

extern void report_error(GError* error);

extern void add_cylinder_description(cylinder_type_t *);
extern void add_people(const char *string);
extern void add_location(const char *string);
extern void remember_event(const char *eventname);
extern void evn_foreach(void (*callback)(const char *, int *, void *), void *data);

extern void dive_list_update_dives(void);
extern void flush_divelist(struct dive *dive);

#define DIVE_ERROR_PARSE 1

const char *weekday(int wday);
const char *monthname(int mon);

#define UTF8_DEGREE "\xc2\xb0"
#define UTF8_SUBSCRIPT_2 "\xe2\x82\x82"

#endif /* DIVE_H */