Parser: make parser (mostly) reentrant

Introduce a parser_state structure, which describes (most) of the
global parser state. Create such a structure in the entry routines
to the parser and pass it down to the individual functions. The
parser state is initialized and freed with the init_parser_state()
and free_parser_state() functions.

The main benefits are:
1) Isolation of parser state.
2) Keeping the global name space tidy.
3) Prevent memory leaks which could happen in truncated files by
   freeing all the parser state after parse.

A somewhat controversial point might be that the individual
parsing functions are split in those that need parser-state and
those that don't. This means that there are now two versions of
the MATCH macro, viz. one for the former and one for the latter.

Signed-off-by: Berthold Stoeger <bstoeger@mail.tuwien.ac.at>
This commit is contained in:
Berthold Stoeger 2018-10-17 18:45:22 +02:00 committed by Dirk Hohndel
parent 343808271c
commit 138f27f65d
7 changed files with 1022 additions and 957 deletions

View file

@ -13,57 +13,57 @@
#include "membuffer.h" #include "membuffer.h"
#include "gettext.h" #include "gettext.h"
extern int cobalt_profile_sample(void *handle, int columns, char **data, char **column) static int cobalt_profile_sample(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
sample_start(); sample_start(state);
if (data[0]) if (data[0])
cur_sample->time.seconds = atoi(data[0]); state->cur_sample->time.seconds = atoi(data[0]);
if (data[1]) if (data[1])
cur_sample->depth.mm = atoi(data[1]); state->cur_sample->depth.mm = atoi(data[1]);
if (data[2]) if (data[2])
cur_sample->temperature.mkelvin = metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0)); state->cur_sample->temperature.mkelvin = state->metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0));
sample_end(); sample_end(state);
return 0; return 0;
} }
extern int cobalt_cylinders(void *handle, int columns, char **data, char **column) static int cobalt_cylinders(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
cylinder_start(); cylinder_start(state);
if (data[0]) if (data[0])
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[0]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = atoi(data[0]) * 10;
if (data[1]) if (data[1])
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[1]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = atoi(data[1]) * 10;
if (data[2]) if (data[2])
cur_dive->cylinder[cur_cylinder_index].start.mbar = psi_to_mbar(atoi(data[2])); state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar = psi_to_mbar(atoi(data[2]));
if (data[3]) if (data[3])
cur_dive->cylinder[cur_cylinder_index].end.mbar = psi_to_mbar(atoi(data[3])); state->cur_dive->cylinder[state->cur_cylinder_index].end.mbar = psi_to_mbar(atoi(data[3]));
if (data[4]) if (data[4])
cur_dive->cylinder[cur_cylinder_index].type.size.mliter = atoi(data[4]) * 100; state->cur_dive->cylinder[state->cur_cylinder_index].type.size.mliter = atoi(data[4]) * 100;
if (data[5]) if (data[5])
cur_dive->cylinder[cur_cylinder_index].gas_used.mliter = atoi(data[5]) * 1000; state->cur_dive->cylinder[state->cur_cylinder_index].gas_used.mliter = atoi(data[5]) * 1000;
cylinder_end(); cylinder_end(state);
return 0; return 0;
} }
extern int cobalt_buddies(void *handle, int columns, char **data, char **column) static int cobalt_buddies(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
if (data[0]) if (data[0])
utf8_string(data[0], &cur_dive->buddy); utf8_string(data[0], &state->cur_dive->buddy);
return 0; return 0;
} }
@ -73,20 +73,20 @@ extern int cobalt_buddies(void *handle, int columns, char **data, char **column)
* Subsurface star rating. * Subsurface star rating.
*/ */
extern int cobalt_visibility(void *handle, int columns, char **data, char **column) static int cobalt_visibility(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle); UNUSED(param);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
UNUSED(data); UNUSED(data);
return 0; return 0;
} }
extern int cobalt_location(void *handle, int columns, char **data, char **column) static int cobalt_location(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
static char *location = NULL; static char *location = NULL;
if (data[0]) { if (data[0]) {
@ -97,7 +97,7 @@ extern int cobalt_location(void *handle, int columns, char **data, char **column
sprintf(tmp, "%s / %s", location, data[0]); sprintf(tmp, "%s / %s", location, data[0]);
free(location); free(location);
location = NULL; location = NULL;
cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(tmp, cur_dive->when); state->cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(tmp, state->cur_dive->when);
free(tmp); free(tmp);
} else { } else {
location = strdup(data[0]); location = strdup(data[0]);
@ -107,13 +107,14 @@ extern int cobalt_location(void *handle, int columns, char **data, char **column
} }
extern int cobalt_dive(void *param, int columns, char **data, char **column) static int cobalt_dive(void *param, int columns, char **data, char **column)
{ {
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
int retval = 0; int retval = 0;
sqlite3 *handle = (sqlite3 *)param; struct parser_state *state = (struct parser_state *)param;
sqlite3 *handle = state->sql_handle;
char *err = NULL; char *err = NULL;
char get_profile_template[] = "select runtime*60,(DepthPressure*10000/SurfacePressure)-10000,p.Temperature from Dive AS d JOIN TrackPoints AS p ON d.Id=p.DiveId where d.Id=%d"; char get_profile_template[] = "select runtime*60,(DepthPressure*10000/SurfacePressure)-10000,p.Temperature from Dive AS d JOIN TrackPoints AS p ON d.Id=p.DiveId where d.Id=%d";
char get_cylinder_template[] = "select FO2,FHe,StartingPressure,EndingPressure,TankSize,TankPressure,TotalConsumption from GasMixes where DiveID=%d and StartingPressure>0 and EndingPressure > 0 group by FO2,FHe"; char get_cylinder_template[] = "select FO2,FHe,StartingPressure,EndingPressure,TankSize,TankPressure,TotalConsumption from GasMixes where DiveID=%d and StartingPressure>0 and EndingPressure > 0 group by FO2,FHe";
@ -123,13 +124,13 @@ extern int cobalt_dive(void *param, int columns, char **data, char **column)
char get_site_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=1"; char get_site_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=1";
char get_buffer[1024]; char get_buffer[1024];
dive_start(); dive_start(state);
cur_dive->number = atoi(data[0]); state->cur_dive->number = atoi(data[0]);
cur_dive->when = (time_t)(atol(data[1])); state->cur_dive->when = (time_t)(atol(data[1]));
if (data[4]) if (data[4])
utf8_string(data[4], &cur_dive->notes); utf8_string(data[4], &state->cur_dive->notes);
/* data[5] should have information on Units used, but I cannot /* data[5] should have information on Units used, but I cannot
* parse it at all based on the sample log I have received. The * parse it at all based on the sample log I have received. The
@ -137,79 +138,79 @@ extern int cobalt_dive(void *param, int columns, char **data, char **column)
* that. * that.
*/ */
metric = 0; state->metric = 0;
/* Cobalt stores the pressures, not the depth */ /* Cobalt stores the pressures, not the depth */
if (data[6]) if (data[6])
cur_dive->dc.maxdepth.mm = atoi(data[6]); state->cur_dive->dc.maxdepth.mm = atoi(data[6]);
if (data[7]) if (data[7])
cur_dive->dc.duration.seconds = atoi(data[7]); state->cur_dive->dc.duration.seconds = atoi(data[7]);
if (data[8]) if (data[8])
cur_dive->dc.surface_pressure.mbar = atoi(data[8]); state->cur_dive->dc.surface_pressure.mbar = atoi(data[8]);
/* /*
* TODO: the deviceid hash should be calculated here. * TODO: the deviceid hash should be calculated here.
*/ */
settings_start(); settings_start(state);
dc_settings_start(); dc_settings_start(state);
if (data[9]) { if (data[9]) {
utf8_string(data[9], &cur_settings.dc.serial_nr); utf8_string(data[9], &state->cur_settings.dc.serial_nr);
cur_settings.dc.deviceid = atoi(data[9]); state->cur_settings.dc.deviceid = atoi(data[9]);
cur_settings.dc.model = strdup("Cobalt import"); state->cur_settings.dc.model = strdup("Cobalt import");
} }
dc_settings_end(); dc_settings_end(state);
settings_end(); settings_end(state);
if (data[9]) { if (data[9]) {
cur_dive->dc.deviceid = atoi(data[9]); state->cur_dive->dc.deviceid = atoi(data[9]);
cur_dive->dc.model = strdup("Cobalt import"); state->cur_dive->dc.model = strdup("Cobalt import");
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_cylinders, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_cylinders, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_cylinders failed.\n"); fprintf(stderr, "%s", "Database query cobalt_cylinders failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_buddy_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_buddy_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_buddies, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_buddies, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_buddies failed.\n"); fprintf(stderr, "%s", "Database query cobalt_buddies failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_visibility_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_visibility_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_visibility, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_visibility, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_visibility failed.\n"); fprintf(stderr, "%s", "Database query cobalt_visibility failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_location_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_location_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_location, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_location, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_location failed.\n"); fprintf(stderr, "%s", "Database query cobalt_location failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_site_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_site_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_location, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_location, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_location (site) failed.\n"); fprintf(stderr, "%s", "Database query cobalt_location (site) failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, cur_dive->number); snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_buffer, &cobalt_profile_sample, 0, &err); retval = sqlite3_exec(handle, get_buffer, &cobalt_profile_sample, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query cobalt_profile_sample failed.\n"); fprintf(stderr, "%s", "Database query cobalt_profile_sample failed.\n");
return 1; return 1;
} }
dive_end(); dive_end(state);
return SQLITE_OK; return SQLITE_OK;
} }
@ -223,11 +224,16 @@ int parse_cobalt_buffer(sqlite3 *handle, const char *url, const char *buffer, in
int retval; int retval;
char *err = NULL; char *err = NULL;
target_table = table; struct parser_state state;
init_parser_state(&state);
state.target_table = table;
state.sql_handle = handle;
char get_dives[] = "select Id,strftime('%s',DiveStartTime),LocationId,'buddy','notes',Units,(MaxDepthPressure*10000/SurfacePressure)-10000,DiveMinutes,SurfacePressure,SerialNumber,'model' from Dive where IsViewDeleted = 0"; char get_dives[] = "select Id,strftime('%s',DiveStartTime),LocationId,'buddy','notes',Units,(MaxDepthPressure*10000/SurfacePressure)-10000,DiveMinutes,SurfacePressure,SerialNumber,'model' from Dive where IsViewDeleted = 0";
retval = sqlite3_exec(handle, get_dives, &cobalt_dive, handle, &err); retval = sqlite3_exec(handle, get_dives, &cobalt_dive, &state, &err);
free_parser_state(&state);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "Database query failed '%s'.\n", url); fprintf(stderr, "Database query failed '%s'.\n", url);
@ -236,4 +242,3 @@ int parse_cobalt_buffer(sqlite3 *handle, const char *url, const char *buffer, in
return 0; return 0;
} }

View file

@ -13,11 +13,11 @@
#include "membuffer.h" #include "membuffer.h"
#include "gettext.h" #include "gettext.h"
extern int divinglog_cylinder(void *handle, int columns, char **data, char **column) static int divinglog_cylinder(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
short dbl = 1; short dbl = 1;
//char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d"; //char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d";
@ -27,13 +27,13 @@ extern int divinglog_cylinder(void *handle, int columns, char **data, char **col
* better to ignore those. * better to ignore those.
*/ */
if (cur_cylinder_index >= MAX_CYLINDERS) if (state->cur_cylinder_index >= MAX_CYLINDERS)
return 0; return 0;
if (data[7] && atoi(data[7]) > 0) if (data[7] && atoi(data[7]) > 0)
dbl = 2; dbl = 2;
cylinder_start(); cylinder_start(state);
/* /*
* Assuming that we have to double the cylinder size, if double * Assuming that we have to double the cylinder size, if double
@ -41,29 +41,29 @@ extern int divinglog_cylinder(void *handle, int columns, char **data, char **col
*/ */
if (data[1] && atoi(data[1]) > 0) if (data[1] && atoi(data[1]) > 0)
cur_dive->cylinder[cur_cylinder_index].type.size.mliter = atol(data[1]) * 1000 * dbl; state->cur_dive->cylinder[state->cur_cylinder_index].type.size.mliter = atol(data[1]) * 1000 * dbl;
if (data[2] && atoi(data[2]) > 0) if (data[2] && atoi(data[2]) > 0)
cur_dive->cylinder[cur_cylinder_index].start.mbar = atol(data[2]) * 1000; state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar = atol(data[2]) * 1000;
if (data[3] && atoi(data[3]) > 0) if (data[3] && atoi(data[3]) > 0)
cur_dive->cylinder[cur_cylinder_index].end.mbar = atol(data[3]) * 1000; state->cur_dive->cylinder[state->cur_cylinder_index].end.mbar = atol(data[3]) * 1000;
if (data[4] && atoi(data[4]) > 0) if (data[4] && atoi(data[4]) > 0)
cur_dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = atol(data[4]) * 1000; state->cur_dive->cylinder[state->cur_cylinder_index].type.workingpressure.mbar = atol(data[4]) * 1000;
if (data[5] && atoi(data[5]) > 0) if (data[5] && atoi(data[5]) > 0)
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atol(data[5]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = atol(data[5]) * 10;
if (data[6] && atoi(data[6]) > 0) if (data[6] && atoi(data[6]) > 0)
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atol(data[6]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = atol(data[6]) * 10;
cylinder_end(); cylinder_end(state);
return 0; return 0;
} }
extern int divinglog_profile(void *handle, int columns, char **data, char **column) static int divinglog_profile(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
int sinterval = 0; int sinterval = 0;
unsigned long time; unsigned long time;
@ -121,11 +121,11 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
time = 0; time = 0;
while (len1 >= 12) { while (len1 >= 12) {
sample_start(); sample_start(state);
cur_sample->time.seconds = time; state->cur_sample->time.seconds = time;
cur_sample->in_deco = ptr1[5] - '0' ? true : false; state->cur_sample->in_deco = ptr1[5] - '0' ? true : false;
cur_sample->depth.mm = atoi_n(ptr1, 5) * 10; state->cur_sample->depth.mm = atoi_n(ptr1, 5) * 10;
if (len2 >= 11) { if (len2 >= 11) {
int temp = atoi_n(ptr2, 3); int temp = atoi_n(ptr2, 3);
@ -133,23 +133,23 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
int tank = atoi_n(ptr2+7, 1); int tank = atoi_n(ptr2+7, 1);
int rbt = atoi_n(ptr2+8, 3) * 60; int rbt = atoi_n(ptr2+8, 3) * 60;
cur_sample->temperature.mkelvin = C_to_mkelvin(temp / 10.0f); state->cur_sample->temperature.mkelvin = C_to_mkelvin(temp / 10.0f);
cur_sample->pressure[0].mbar = pressure * 100; state->cur_sample->pressure[0].mbar = pressure * 100;
cur_sample->rbt.seconds = rbt; state->cur_sample->rbt.seconds = rbt;
if (oldcyl != tank) { if (oldcyl != tank) {
struct gasmix mix = cur_dive->cylinder[tank].gasmix; struct gasmix mix = state->cur_dive->cylinder[tank].gasmix;
int o2 = get_o2(mix); int o2 = get_o2(mix);
int he = get_he(mix); int he = get_he(mix);
event_start(); event_start(state);
cur_event.time.seconds = time; state->cur_event.time.seconds = time;
strcpy(cur_event.name, "gaschange"); strcpy(state->cur_event.name, "gaschange");
o2 = (o2 + 5) / 10; o2 = (o2 + 5) / 10;
he = (he + 5) / 10; he = (he + 5) / 10;
cur_event.value = o2 + (he << 16); state->cur_event.value = o2 + (he << 16);
event_end(); event_end(state);
oldcyl = tank; oldcyl = tank;
} }
@ -157,7 +157,7 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
} }
if (len3 >= 14) { if (len3 >= 14) {
cur_sample->heartbeat = atoi_n(ptr3+8, 3); state->cur_sample->heartbeat = atoi_n(ptr3+8, 3);
ptr3 += 14; len3 -= 14; ptr3 += 14; len3 -= 14;
} }
@ -167,15 +167,15 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
* either 0 or TTS when in deco. * either 0 or TTS when in deco.
*/ */
int val = atoi_n(ptr4, 3); int val = atoi_n(ptr4, 3);
if (cur_sample->in_deco) { if (state->cur_sample->in_deco) {
cur_sample->ndl.seconds = 0; state->cur_sample->ndl.seconds = 0;
if (val) if (val)
cur_sample->tts.seconds = val * 60; state->cur_sample->tts.seconds = val * 60;
} else { } else {
cur_sample->ndl.seconds = val * 60; state->cur_sample->ndl.seconds = val * 60;
} }
cur_sample->stoptime.seconds = atoi_n(ptr4+3, 3) * 60; state->cur_sample->stoptime.seconds = atoi_n(ptr4+3, 3) * 60;
cur_sample->stopdepth.mm = atoi_n(ptr4+6, 3) * 1000; state->cur_sample->stopdepth.mm = atoi_n(ptr4+6, 3) * 1000;
ptr4 += 9; len4 -= 9; ptr4 += 9; len4 -= 9;
} }
@ -203,15 +203,15 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
int setpoint = atoi_n(ptr5 + 17, 2); int setpoint = atoi_n(ptr5 + 17, 2);
if (ppo2_1 > 0) if (ppo2_1 > 0)
cur_sample->o2sensor[0].mbar = ppo2_1 * 100; state->cur_sample->o2sensor[0].mbar = ppo2_1 * 100;
if (ppo2_2 > 0) if (ppo2_2 > 0)
cur_sample->o2sensor[1].mbar = ppo2_2 * 100; state->cur_sample->o2sensor[1].mbar = ppo2_2 * 100;
if (ppo2_3 > 0) if (ppo2_3 > 0)
cur_sample->o2sensor[2].mbar = ppo2_3 * 100; state->cur_sample->o2sensor[2].mbar = ppo2_3 * 100;
if (cns > 0) if (cns > 0)
cur_sample->cns = lrintf(cns / 10.0f); state->cur_sample->cns = lrintf(cns / 10.0f);
if (setpoint > 0) if (setpoint > 0)
cur_sample->setpoint.mbar = setpoint * 100; state->cur_sample->setpoint.mbar = setpoint * 100;
ptr5 += 19; len5 -= 19; ptr5 += 19; len5 -= 19;
} }
@ -219,44 +219,44 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
* Count the number of o2 sensors * Count the number of o2 sensors
*/ */
if (!cur_dive->dc.no_o2sensors && (cur_sample->o2sensor[0].mbar || cur_sample->o2sensor[1].mbar || cur_sample->o2sensor[2].mbar)) { if (!state->cur_dive->dc.no_o2sensors && (state->cur_sample->o2sensor[0].mbar || state->cur_sample->o2sensor[1].mbar || state->cur_sample->o2sensor[2].mbar)) {
cur_dive->dc.no_o2sensors = cur_sample->o2sensor[0].mbar ? 1 : 0 + state->cur_dive->dc.no_o2sensors = state->cur_sample->o2sensor[0].mbar ? 1 : 0 +
cur_sample->o2sensor[1].mbar ? 1 : 0 + state->cur_sample->o2sensor[1].mbar ? 1 : 0 +
cur_sample->o2sensor[2].mbar ? 1 : 0; state->cur_sample->o2sensor[2].mbar ? 1 : 0;
} }
sample_end(); sample_end(state);
/* Remaining bottom time warning */ /* Remaining bottom time warning */
if (ptr1[6] - '0') { if (ptr1[6] - '0') {
event_start(); event_start(state);
cur_event.time.seconds = time; state->cur_event.time.seconds = time;
strcpy(cur_event.name, "rbt"); strcpy(state->cur_event.name, "rbt");
event_end(); event_end(state);
} }
/* Ascent warning */ /* Ascent warning */
if (ptr1[7] - '0') { if (ptr1[7] - '0') {
event_start(); event_start(state);
cur_event.time.seconds = time; state->cur_event.time.seconds = time;
strcpy(cur_event.name, "ascent"); strcpy(state->cur_event.name, "ascent");
event_end(); event_end(state);
} }
/* Deco stop ignored */ /* Deco stop ignored */
if (ptr1[8] - '0') { if (ptr1[8] - '0') {
event_start(); event_start(state);
cur_event.time.seconds = time; state->cur_event.time.seconds = time;
strcpy(cur_event.name, "violation"); strcpy(state->cur_event.name, "violation");
event_end(); event_end(state);
} }
/* Workload warning */ /* Workload warning */
if (ptr1[9] - '0') { if (ptr1[9] - '0') {
event_start(); event_start(state);
cur_event.time.seconds = time; state->cur_event.time.seconds = time;
strcpy(cur_event.name, "workload"); strcpy(state->cur_event.name, "workload");
event_end(); event_end(state);
} }
ptr1 += 12; len1 -= 12; ptr1 += 12; len1 -= 12;
@ -266,56 +266,57 @@ extern int divinglog_profile(void *handle, int columns, char **data, char **colu
return 0; return 0;
} }
extern int divinglog_dive(void *param, int columns, char **data, char **column) static int divinglog_dive(void *param, int columns, char **data, char **column)
{ {
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
int retval = 0, diveid; int retval = 0, diveid;
sqlite3 *handle = (sqlite3 *)param; struct parser_state *state = (struct parser_state *)param;
sqlite3 *handle = state->sql_handle;
char *err = NULL; char *err = NULL;
char get_profile_template[] = "select ProfileInt,Profile,Profile2,Profile3,Profile4,Profile5 from Logbook where ID = %d"; char get_profile_template[] = "select ProfileInt,Profile,Profile2,Profile3,Profile4,Profile5 from Logbook where ID = %d";
char get_cylinder0_template[] = "select 0,TankSize,PresS,PresE,PresW,O2,He,DblTank from Logbook where ID = %d"; char get_cylinder0_template[] = "select 0,TankSize,PresS,PresE,PresW,O2,He,DblTank from Logbook where ID = %d";
char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d order by TankID"; char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d order by TankID";
char get_buffer[1024]; char get_buffer[1024];
dive_start(); dive_start(state);
diveid = atoi(data[13]); diveid = atoi(data[13]);
cur_dive->number = atoi(data[0]); state->cur_dive->number = atoi(data[0]);
cur_dive->when = (time_t)(atol(data[1])); state->cur_dive->when = (time_t)(atol(data[1]));
if (data[2]) if (data[2])
cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(data[2], cur_dive->when); state->cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(data[2], state->cur_dive->when);
if (data[3]) if (data[3])
utf8_string(data[3], &cur_dive->buddy); utf8_string(data[3], &state->cur_dive->buddy);
if (data[4]) if (data[4])
utf8_string(data[4], &cur_dive->notes); utf8_string(data[4], &state->cur_dive->notes);
if (data[5]) if (data[5])
cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[5], NULL, 0) * 1000); state->cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[5], NULL, 0) * 1000);
if (data[6]) if (data[6])
cur_dive->dc.duration.seconds = atoi(data[6]) * 60; state->cur_dive->dc.duration.seconds = atoi(data[6]) * 60;
if (data[7]) if (data[7])
utf8_string(data[7], &cur_dive->divemaster); utf8_string(data[7], &state->cur_dive->divemaster);
if (data[8]) if (data[8])
cur_dive->airtemp.mkelvin = C_to_mkelvin(atol(data[8])); state->cur_dive->airtemp.mkelvin = C_to_mkelvin(atol(data[8]));
if (data[9]) if (data[9])
cur_dive->watertemp.mkelvin = C_to_mkelvin(atol(data[9])); state->cur_dive->watertemp.mkelvin = C_to_mkelvin(atol(data[9]));
if (data[10]) { if (data[10]) {
cur_dive->weightsystem[0].weight.grams = atol(data[10]) * 1000; state->cur_dive->weightsystem[0].weight.grams = atol(data[10]) * 1000;
cur_dive->weightsystem[0].description = strdup(translate("gettextFromC", "unknown")); state->cur_dive->weightsystem[0].description = strdup(translate("gettextFromC", "unknown"));
} }
if (data[11]) if (data[11])
cur_dive->suit = strdup(data[11]); state->cur_dive->suit = strdup(data[11]);
/* Divinglog has following visibility options: good, medium, bad */ /* Divinglog has following visibility options: good, medium, bad */
if (data[14]) { if (data[14]) {
@ -323,37 +324,37 @@ extern int divinglog_dive(void *param, int columns, char **data, char **column)
case '0': case '0':
break; break;
case '1': case '1':
cur_dive->visibility = 5; state->cur_dive->visibility = 5;
break; break;
case '2': case '2':
cur_dive->visibility = 3; state->cur_dive->visibility = 3;
break; break;
case '3': case '3':
cur_dive->visibility = 1; state->cur_dive->visibility = 1;
break; break;
default: default:
break; break;
} }
} }
settings_start(); settings_start(state);
dc_settings_start(); dc_settings_start(state);
if (data[12]) { if (data[12]) {
cur_dive->dc.model = strdup(data[12]); state->cur_dive->dc.model = strdup(data[12]);
} else { } else {
cur_settings.dc.model = strdup("Divinglog import"); state->cur_settings.dc.model = strdup("Divinglog import");
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder0_template, diveid); snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder0_template, diveid);
retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, 0, &err); retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query divinglog_cylinder0 failed.\n"); fprintf(stderr, "%s", "Database query divinglog_cylinder0 failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, diveid); snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, diveid);
retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, 0, &err); retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query divinglog_cylinder failed.\n"); fprintf(stderr, "%s", "Database query divinglog_cylinder failed.\n");
return 1; return 1;
@ -365,31 +366,31 @@ extern int divinglog_dive(void *param, int columns, char **data, char **column)
case '0': case '0':
break; break;
case '1': case '1':
cur_dive->dc.divemode = PSCR; state->cur_dive->dc.divemode = PSCR;
break; break;
case '2': case '2':
cur_dive->dc.divemode = CCR; state->cur_dive->dc.divemode = CCR;
break; break;
} }
} }
dc_settings_end(); dc_settings_end(state);
settings_end(); settings_end(state);
if (data[12]) { if (data[12]) {
cur_dive->dc.model = strdup(data[12]); state->cur_dive->dc.model = strdup(data[12]);
} else { } else {
cur_dive->dc.model = strdup("Divinglog import"); state->cur_dive->dc.model = strdup("Divinglog import");
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, diveid); snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, diveid);
retval = sqlite3_exec(handle, get_buffer, &divinglog_profile, 0, &err); retval = sqlite3_exec(handle, get_buffer, &divinglog_profile, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query divinglog_profile failed.\n"); fprintf(stderr, "%s", "Database query divinglog_profile failed.\n");
return 1; return 1;
} }
dive_end(); dive_end(state);
return SQLITE_OK; return SQLITE_OK;
} }
@ -403,11 +404,16 @@ int parse_divinglog_buffer(sqlite3 *handle, const char *url, const char *buffer,
int retval; int retval;
char *err = NULL; char *err = NULL;
target_table = table; struct parser_state state;
init_parser_state(&state);
state.target_table = table;
state.sql_handle = handle;
char get_dives[] = "select Number,strftime('%s',Divedate || ' ' || ifnull(Entrytime,'00:00')),Country || ' - ' || City || ' - ' || Place,Buddy,Comments,Depth,Divetime,Divemaster,Airtemp,Watertemp,Weight,Divesuit,Computer,ID,Visibility,SupplyType from Logbook where UUID not in (select UUID from DeletedRecords)"; char get_dives[] = "select Number,strftime('%s',Divedate || ' ' || ifnull(Entrytime,'00:00')),Country || ' - ' || City || ' - ' || Place,Buddy,Comments,Depth,Divetime,Divemaster,Airtemp,Watertemp,Weight,Divesuit,Computer,ID,Visibility,SupplyType from Logbook where UUID not in (select UUID from DeletedRecords)";
retval = sqlite3_exec(handle, get_dives, &divinglog_dive, handle, &err); retval = sqlite3_exec(handle, get_dives, &divinglog_dive, &state, &err);
free_parser_state(&state);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "Database query failed '%s'.\n", url); fprintf(stderr, "Database query failed '%s'.\n", url);

View file

@ -13,11 +13,11 @@
#include "membuffer.h" #include "membuffer.h"
#include "gettext.h" #include "gettext.h"
extern int shearwater_cylinders(void *handle, int columns, char **data, char **column) static int shearwater_cylinders(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
int o2 = lrint(strtod_flags(data[0], NULL, 0) * 1000); int o2 = lrint(strtod_flags(data[0], NULL, 0) * 1000);
int he = lrint(strtod_flags(data[1], NULL, 0) * 1000); int he = lrint(strtod_flags(data[1], NULL, 0) * 1000);
@ -27,19 +27,19 @@ extern int shearwater_cylinders(void *handle, int columns, char **data, char **c
if (o2 == 990 && he == 0) if (o2 == 990 && he == 0)
o2 = 1000; o2 = 1000;
cylinder_start(); cylinder_start(state);
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = o2; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = o2;
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = he; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = he;
cylinder_end(); cylinder_end(state);
return 0; return 0;
} }
extern int shearwater_changes(void *handle, int columns, char **data, char **column) static int shearwater_changes(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
if (columns != 3) { if (columns != 3) {
return 1; return 1;
@ -58,148 +58,149 @@ extern int shearwater_changes(void *handle, int columns, char **data, char **col
// Find the cylinder index // Find the cylinder index
int i; int i;
bool found = false; bool found = false;
for (i = 0; i < cur_cylinder_index; ++i) { for (i = 0; i < state->cur_cylinder_index; ++i) {
if (cur_dive->cylinder[i].gasmix.o2.permille == o2 && cur_dive->cylinder[i].gasmix.he.permille == he) { if (state->cur_dive->cylinder[i].gasmix.o2.permille == o2 && state->cur_dive->cylinder[i].gasmix.he.permille == he) {
found = true; found = true;
break; break;
} }
} }
if (!found) { if (!found) {
// Cylinder not found, creating a new one // Cylinder not found, creating a new one
cylinder_start(); cylinder_start(state);
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = o2; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = o2;
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = he; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = he;
cylinder_end(); cylinder_end(state);
i = cur_cylinder_index; i = state->cur_cylinder_index;
} }
add_gas_switch_event(cur_dive, get_dc(), atoi(data[0]), i); add_gas_switch_event(state->cur_dive, get_dc(state), atoi(data[0]), i);
return 0; return 0;
} }
extern int shearwater_profile_sample(void *handle, int columns, char **data, char **column) static int shearwater_profile_sample(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
int d6, d7; int d6, d7;
sample_start(); sample_start(state);
if (data[0]) if (data[0])
cur_sample->time.seconds = atoi(data[0]); state->cur_sample->time.seconds = atoi(data[0]);
if (data[1]) if (data[1])
cur_sample->depth.mm = metric ? lrint(strtod_flags(data[1], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[1], NULL, 0)); state->cur_sample->depth.mm = state->metric ? lrint(strtod_flags(data[1], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[1], NULL, 0));
if (data[2]) if (data[2])
cur_sample->temperature.mkelvin = metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0)); state->cur_sample->temperature.mkelvin = state->metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0));
if (data[3]) { if (data[3]) {
cur_sample->setpoint.mbar = lrint(strtod_flags(data[3], NULL, 0) * 1000); state->cur_sample->setpoint.mbar = lrint(strtod_flags(data[3], NULL, 0) * 1000);
} }
if (data[4]) if (data[4])
cur_sample->ndl.seconds = atoi(data[4]) * 60; state->cur_sample->ndl.seconds = atoi(data[4]) * 60;
if (data[5]) if (data[5])
cur_sample->cns = atoi(data[5]); state->cur_sample->cns = atoi(data[5]);
if (data[6]) { if (data[6]) {
d6 = atoi(data[6]); d6 = atoi(data[6]);
if (d6 > 0) { if (d6 > 0) {
cur_sample->stopdepth.mm = metric ? d6 * 1000 : feet_to_mm(d6); state->cur_sample->stopdepth.mm = state->metric ? d6 * 1000 : feet_to_mm(d6);
cur_sample->in_deco = 1; state->cur_sample->in_deco = 1;
} else if (data[7]) { } else if (data[7]) {
d7 = atoi(data[7]); d7 = atoi(data[7]);
if (d7 > 0) { if (d7 > 0) {
cur_sample->stopdepth.mm = metric ? d7 * 1000 : feet_to_mm(d7); state->cur_sample->stopdepth.mm = state->metric ? d7 * 1000 : feet_to_mm(d7);
if (data[8]) if (data[8])
cur_sample->stoptime.seconds = atoi(data[8]) * 60; state->cur_sample->stoptime.seconds = atoi(data[8]) * 60;
cur_sample->in_deco = 1; state->cur_sample->in_deco = 1;
} else { } else {
cur_sample->in_deco = 0; state->cur_sample->in_deco = 0;
} }
} else { } else {
cur_sample->in_deco = 0; state->cur_sample->in_deco = 0;
} }
} }
/* We don't actually have data[3], but it should appear in the /* We don't actually have data[3], but it should appear in the
* SQL query at some point. * SQL query at some point.
if (data[3]) if (data[3])
cur_sample->pressure[0].mbar = metric ? atoi(data[3]) * 1000 : psi_to_mbar(atoi(data[3])); state->cur_sample->pressure[0].mbar = state->metric ? atoi(data[3]) * 1000 : psi_to_mbar(atoi(data[3]));
*/ */
sample_end(); sample_end(state);
return 0; return 0;
} }
extern int shearwater_ai_profile_sample(void *handle, int columns, char **data, char **column) static int shearwater_ai_profile_sample(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
int d6, d9; int d6, d9;
sample_start(); sample_start(state);
if (data[0]) if (data[0])
cur_sample->time.seconds = atoi(data[0]); state->cur_sample->time.seconds = atoi(data[0]);
if (data[1]) if (data[1])
cur_sample->depth.mm = metric ? lrint(strtod_flags(data[1], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[1], NULL, 0)); state->cur_sample->depth.mm = state->metric ? lrint(strtod_flags(data[1], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[1], NULL, 0));
if (data[2]) if (data[2])
cur_sample->temperature.mkelvin = metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0)); state->cur_sample->temperature.mkelvin = state->metric ? C_to_mkelvin(strtod_flags(data[2], NULL, 0)) : F_to_mkelvin(strtod_flags(data[2], NULL, 0));
if (data[3]) { if (data[3]) {
cur_sample->setpoint.mbar = lrint(strtod_flags(data[3], NULL, 0) * 1000); state->cur_sample->setpoint.mbar = lrint(strtod_flags(data[3], NULL, 0) * 1000);
} }
if (data[4]) if (data[4])
cur_sample->ndl.seconds = atoi(data[4]) * 60; state->cur_sample->ndl.seconds = atoi(data[4]) * 60;
if (data[5]) if (data[5])
cur_sample->cns = atoi(data[5]); state->cur_sample->cns = atoi(data[5]);
if (data[6]) { if (data[6]) {
d6 = atoi(data[6]); d6 = atoi(data[6]);
if (d6 > 0) { if (d6 > 0) {
cur_sample->stopdepth.mm = metric ? d6 * 1000 : feet_to_mm(d6); state->cur_sample->stopdepth.mm = state->metric ? d6 * 1000 : feet_to_mm(d6);
cur_sample->in_deco = 1; state->cur_sample->in_deco = 1;
} else if (data[9]) { } else if (data[9]) {
d9 = atoi(data[9]); d9 = atoi(data[9]);
if (d9 > 0) { if (d9 > 0) {
cur_sample->stopdepth.mm = metric ? d9 * 1000 : feet_to_mm(d9); state->cur_sample->stopdepth.mm = state->metric ? d9 * 1000 : feet_to_mm(d9);
if (data[10]) if (data[10])
cur_sample->stoptime.seconds = atoi(data[10]) * 60; state->cur_sample->stoptime.seconds = atoi(data[10]) * 60;
cur_sample->in_deco = 1; state->cur_sample->in_deco = 1;
} else { } else {
cur_sample->in_deco = 0; state->cur_sample->in_deco = 0;
} }
} else { } else {
cur_sample->in_deco = 0; state->cur_sample->in_deco = 0;
} }
} }
/* Weird unit conversion but seems to produce correct results. /* Weird unit conversion but seems to produce correct results.
* Also missing values seems to be reported as a 4092 (564 bar) */ * Also missing values seems to be reported as a 4092 (564 bar) */
if (data[7] && atoi(data[7]) != 4092) { if (data[7] && atoi(data[7]) != 4092) {
cur_sample->pressure[0].mbar = psi_to_mbar(atoi(data[7])) * 2; state->cur_sample->pressure[0].mbar = psi_to_mbar(atoi(data[7])) * 2;
} }
if (data[8] && atoi(data[8]) != 4092) if (data[8] && atoi(data[8]) != 4092)
cur_sample->pressure[1].mbar = psi_to_mbar(atoi(data[8])) * 2; state->cur_sample->pressure[1].mbar = psi_to_mbar(atoi(data[8])) * 2;
sample_end(); sample_end(state);
return 0; return 0;
} }
extern int shearwater_mode(void *handle, int columns, char **data, char **column) static int shearwater_mode(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
if (data[0]) if (data[0])
cur_dive->dc.divemode = atoi(data[0]) == 0 ? CCR : OC; state->cur_dive->dc.divemode = atoi(data[0]) == 0 ? CCR : OC;
return 0; return 0;
} }
extern int shearwater_dive(void *param, int columns, char **data, char **column) static int shearwater_dive(void *param, int columns, char **data, char **column)
{ {
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
int retval = 0; int retval = 0;
sqlite3 *handle = (sqlite3 *)param; struct parser_state *state = (struct parser_state *)param;
sqlite3 *handle = state->sql_handle;
char *err = NULL; char *err = NULL;
char get_profile_template[] = "select currentTime,currentDepth,waterTemp,averagePPO2,currentNdl,CNSPercent,decoCeiling,firstStopDepth,firstStopTime from dive_log_records where diveLogId=%d"; char get_profile_template[] = "select currentTime,currentDepth,waterTemp,averagePPO2,currentNdl,CNSPercent,decoCeiling,firstStopDepth,firstStopTime from dive_log_records where diveLogId=%d";
char get_profile_template_ai[] = "select currentTime,currentDepth,waterTemp,averagePPO2,currentNdl,CNSPercent,decoCeiling,aiSensor0_PressurePSI,aiSensor1_PressurePSI,firstStopDepth,firstStopTime from dive_log_records where diveLogId = %d"; char get_profile_template_ai[] = "select currentTime,currentDepth,waterTemp,averagePPO2,currentNdl,CNSPercent,decoCeiling,aiSensor0_PressurePSI,aiSensor1_PressurePSI,firstStopDepth,firstStopTime from dive_log_records where diveLogId = %d";
@ -208,74 +209,74 @@ extern int shearwater_dive(void *param, int columns, char **data, char **column)
char get_mode_template[] = "select distinct currentCircuitSetting from dive_log_records where diveLogId = %d"; char get_mode_template[] = "select distinct currentCircuitSetting from dive_log_records where diveLogId = %d";
char get_buffer[1024]; char get_buffer[1024];
dive_start(); dive_start(state);
cur_dive->number = atoi(data[0]); state->cur_dive->number = atoi(data[0]);
cur_dive->when = (time_t)(atol(data[1])); state->cur_dive->when = (time_t)(atol(data[1]));
int dive_id = atoi(data[11]); int dive_id = atoi(data[11]);
if (data[2]) if (data[2])
add_dive_site(data[2], cur_dive); add_dive_site(data[2], state->cur_dive, state);
if (data[3]) if (data[3])
utf8_string(data[3], &cur_dive->buddy); utf8_string(data[3], &state->cur_dive->buddy);
if (data[4]) if (data[4])
utf8_string(data[4], &cur_dive->notes); utf8_string(data[4], &state->cur_dive->notes);
metric = atoi(data[5]) == 1 ? 0 : 1; state->metric = atoi(data[5]) == 1 ? 0 : 1;
/* TODO: verify that metric calculation is correct */ /* TODO: verify that metric calculation is correct */
if (data[6]) if (data[6])
cur_dive->dc.maxdepth.mm = metric ? lrint(strtod_flags(data[6], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[6], NULL, 0)); state->cur_dive->dc.maxdepth.mm = state->metric ? lrint(strtod_flags(data[6], NULL, 0) * 1000) : feet_to_mm(strtod_flags(data[6], NULL, 0));
if (data[7]) if (data[7])
cur_dive->dc.duration.seconds = atoi(data[7]) * 60; state->cur_dive->dc.duration.seconds = atoi(data[7]) * 60;
if (data[8]) if (data[8])
cur_dive->dc.surface_pressure.mbar = atoi(data[8]); state->cur_dive->dc.surface_pressure.mbar = atoi(data[8]);
/* /*
* TODO: the deviceid hash should be calculated here. * TODO: the deviceid hash should be calculated here.
*/ */
settings_start(); settings_start(state);
dc_settings_start(); dc_settings_start(state);
if (data[9]) if (data[9])
utf8_string(data[9], &cur_settings.dc.serial_nr); utf8_string(data[9], &state->cur_settings.dc.serial_nr);
if (data[10]) { if (data[10]) {
switch (atoi(data[10])) { switch (atoi(data[10])) {
case 2: case 2:
cur_settings.dc.model = strdup("Shearwater Petrel/Perdix"); state->cur_settings.dc.model = strdup("Shearwater Petrel/Perdix");
break; break;
case 4: case 4:
cur_settings.dc.model = strdup("Shearwater Predator"); state->cur_settings.dc.model = strdup("Shearwater Predator");
break; break;
default: default:
cur_settings.dc.model = strdup("Shearwater import"); state->cur_settings.dc.model = strdup("Shearwater import");
break; break;
} }
} }
cur_settings.dc.deviceid = atoi(data[9]); state->cur_settings.dc.deviceid = atoi(data[9]);
dc_settings_end(); dc_settings_end(state);
settings_end(); settings_end(state);
if (data[10]) { if (data[10]) {
switch (atoi(data[10])) { switch (atoi(data[10])) {
case 2: case 2:
cur_dive->dc.model = strdup("Shearwater Petrel/Perdix"); state->cur_dive->dc.model = strdup("Shearwater Petrel/Perdix");
break; break;
case 4: case 4:
cur_dive->dc.model = strdup("Shearwater Predator"); state->cur_dive->dc.model = strdup("Shearwater Predator");
break; break;
default: default:
cur_dive->dc.model = strdup("Shearwater import"); state->cur_dive->dc.model = strdup("Shearwater import");
break; break;
} }
} }
if (data[11]) { if (data[11]) {
snprintf(get_buffer, sizeof(get_buffer) - 1, get_mode_template, dive_id); snprintf(get_buffer, sizeof(get_buffer) - 1, get_mode_template, dive_id);
retval = sqlite3_exec(handle, get_buffer, &shearwater_mode, 0, &err); retval = sqlite3_exec(handle, get_buffer, &shearwater_mode, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query shearwater_mode failed.\n"); fprintf(stderr, "%s", "Database query shearwater_mode failed.\n");
return 1; return 1;
@ -283,31 +284,31 @@ extern int shearwater_dive(void *param, int columns, char **data, char **column)
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, dive_id); snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, dive_id);
retval = sqlite3_exec(handle, get_buffer, &shearwater_cylinders, 0, &err); retval = sqlite3_exec(handle, get_buffer, &shearwater_cylinders, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query shearwater_cylinders failed.\n"); fprintf(stderr, "%s", "Database query shearwater_cylinders failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_changes_template, dive_id); snprintf(get_buffer, sizeof(get_buffer) - 1, get_changes_template, dive_id);
retval = sqlite3_exec(handle, get_buffer, &shearwater_changes, 0, &err); retval = sqlite3_exec(handle, get_buffer, &shearwater_changes, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query shearwater_changes failed.\n"); fprintf(stderr, "%s", "Database query shearwater_changes failed.\n");
return 1; return 1;
} }
snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template_ai, dive_id); snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template_ai, dive_id);
retval = sqlite3_exec(handle, get_buffer, &shearwater_ai_profile_sample, 0, &err); retval = sqlite3_exec(handle, get_buffer, &shearwater_ai_profile_sample, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, dive_id); snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, dive_id);
retval = sqlite3_exec(handle, get_buffer, &shearwater_profile_sample, 0, &err); retval = sqlite3_exec(handle, get_buffer, &shearwater_profile_sample, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query shearwater_profile_sample failed.\n"); fprintf(stderr, "%s", "Database query shearwater_profile_sample failed.\n");
return 1; return 1;
} }
} }
dive_end(); dive_end(state);
return SQLITE_OK; return SQLITE_OK;
} }
@ -320,11 +321,16 @@ int parse_shearwater_buffer(sqlite3 *handle, const char *url, const char *buffer
int retval; int retval;
char *err = NULL; char *err = NULL;
target_table = table; struct parser_state state;
init_parser_state(&state);
state.target_table = table;
state.sql_handle = handle;
char get_dives[] = "select l.number,timestamp,location||' / '||site,buddy,notes,imperialUnits,maxDepth,maxTime,startSurfacePressure,computerSerial,computerModel,i.diveId FROM dive_info AS i JOIN dive_logs AS l ON i.diveId=l.diveId"; char get_dives[] = "select l.number,timestamp,location||' / '||site,buddy,notes,imperialUnits,maxDepth,maxTime,startSurfacePressure,computerSerial,computerModel,i.diveId FROM dive_info AS i JOIN dive_logs AS l ON i.diveId=l.diveId";
retval = sqlite3_exec(handle, get_dives, &shearwater_dive, handle, &err); retval = sqlite3_exec(handle, get_dives, &shearwater_dive, &state, &err);
free_parser_state(&state);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "Database query failed '%s'.\n", url); fprintf(stderr, "Database query failed '%s'.\n", url);

View file

@ -13,122 +13,122 @@
#include "membuffer.h" #include "membuffer.h"
#include "gettext.h" #include "gettext.h"
extern int dm4_events(void *handle, int columns, char **data, char **column) static int dm4_events(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
event_start(); event_start(state);
if (data[1]) if (data[1])
cur_event.time.seconds = atoi(data[1]); state->cur_event.time.seconds = atoi(data[1]);
if (data[2]) { if (data[2]) {
switch (atoi(data[2])) { switch (atoi(data[2])) {
case 1: case 1:
/* 1 Mandatory Safety Stop */ /* 1 Mandatory Safety Stop */
strcpy(cur_event.name, "safety stop (mandatory)"); strcpy(state->cur_event.name, "safety stop (mandatory)");
break; break;
case 3: case 3:
/* 3 Deco */ /* 3 Deco */
/* What is Subsurface's term for going to /* What is Subsurface's term for going to
* deco? */ * deco? */
strcpy(cur_event.name, "deco"); strcpy(state->cur_event.name, "deco");
break; break;
case 4: case 4:
/* 4 Ascent warning */ /* 4 Ascent warning */
strcpy(cur_event.name, "ascent"); strcpy(state->cur_event.name, "ascent");
break; break;
case 5: case 5:
/* 5 Ceiling broken */ /* 5 Ceiling broken */
strcpy(cur_event.name, "violation"); strcpy(state->cur_event.name, "violation");
break; break;
case 6: case 6:
/* 6 Mandatory safety stop ceiling error */ /* 6 Mandatory safety stop ceiling error */
strcpy(cur_event.name, "violation"); strcpy(state->cur_event.name, "violation");
break; break;
case 7: case 7:
/* 7 Below deco floor */ /* 7 Below deco floor */
strcpy(cur_event.name, "below floor"); strcpy(state->cur_event.name, "below floor");
break; break;
case 8: case 8:
/* 8 Dive time alarm */ /* 8 Dive time alarm */
strcpy(cur_event.name, "divetime"); strcpy(state->cur_event.name, "divetime");
break; break;
case 9: case 9:
/* 9 Depth alarm */ /* 9 Depth alarm */
strcpy(cur_event.name, "maxdepth"); strcpy(state->cur_event.name, "maxdepth");
break; break;
case 10: case 10:
/* 10 OLF 80% */ /* 10 OLF 80% */
case 11: case 11:
/* 11 OLF 100% */ /* 11 OLF 100% */
strcpy(cur_event.name, "OLF"); strcpy(state->cur_event.name, "OLF");
break; break;
case 12: case 12:
/* 12 High pO₂ */ /* 12 High pO₂ */
strcpy(cur_event.name, "PO2"); strcpy(state->cur_event.name, "PO2");
break; break;
case 13: case 13:
/* 13 Air time */ /* 13 Air time */
strcpy(cur_event.name, "airtime"); strcpy(state->cur_event.name, "airtime");
break; break;
case 17: case 17:
/* 17 Ascent warning */ /* 17 Ascent warning */
strcpy(cur_event.name, "ascent"); strcpy(state->cur_event.name, "ascent");
break; break;
case 18: case 18:
/* 18 Ceiling error */ /* 18 Ceiling error */
strcpy(cur_event.name, "ceiling"); strcpy(state->cur_event.name, "ceiling");
break; break;
case 19: case 19:
/* 19 Surfaced */ /* 19 Surfaced */
strcpy(cur_event.name, "surface"); strcpy(state->cur_event.name, "surface");
break; break;
case 20: case 20:
/* 20 Deco */ /* 20 Deco */
strcpy(cur_event.name, "deco"); strcpy(state->cur_event.name, "deco");
break; break;
case 22: case 22:
case 32: case 32:
/* 22 Mandatory safety stop violation */ /* 22 Mandatory safety stop violation */
/* 32 Deep stop violation */ /* 32 Deep stop violation */
strcpy(cur_event.name, "violation"); strcpy(state->cur_event.name, "violation");
break; break;
case 30: case 30:
/* Tissue level warning */ /* Tissue level warning */
strcpy(cur_event.name, "tissue warning"); strcpy(state->cur_event.name, "tissue warning");
break; break;
case 37: case 37:
/* Tank pressure alarm */ /* Tank pressure alarm */
strcpy(cur_event.name, "tank pressure"); strcpy(state->cur_event.name, "tank pressure");
break; break;
case 257: case 257:
/* 257 Dive active */ /* 257 Dive active */
/* This seems to be given after surface when /* This seems to be given after surface when
* descending again. */ * descending again. */
strcpy(cur_event.name, "surface"); strcpy(state->cur_event.name, "surface");
break; break;
case 258: case 258:
/* 258 Bookmark */ /* 258 Bookmark */
if (data[3]) { if (data[3]) {
strcpy(cur_event.name, "heading"); strcpy(state->cur_event.name, "heading");
cur_event.value = atoi(data[3]); state->cur_event.value = atoi(data[3]);
} else { } else {
strcpy(cur_event.name, "bookmark"); strcpy(state->cur_event.name, "bookmark");
} }
break; break;
case 259: case 259:
/* Deep stop */ /* Deep stop */
strcpy(cur_event.name, "Deep stop"); strcpy(state->cur_event.name, "Deep stop");
break; break;
case 260: case 260:
/* Deep stop */ /* Deep stop */
strcpy(cur_event.name, "Deep stop cleared"); strcpy(state->cur_event.name, "Deep stop cleared");
break; break;
case 266: case 266:
/* Mandatory safety stop activated */ /* Mandatory safety stop activated */
strcpy(cur_event.name, "safety stop (mandatory)"); strcpy(state->cur_event.name, "safety stop (mandatory)");
break; break;
case 267: case 267:
/* Mandatory safety stop deactivated */ /* Mandatory safety stop deactivated */
@ -136,35 +136,36 @@ extern int dm4_events(void *handle, int columns, char **data, char **column)
* profile so skipping as well for now */ * profile so skipping as well for now */
break; break;
default: default:
strcpy(cur_event.name, "unknown"); strcpy(state->cur_event.name, "unknown");
cur_event.value = atoi(data[2]); state->cur_event.value = atoi(data[2]);
break; break;
} }
} }
event_end(); event_end(state);
return 0; return 0;
} }
extern int dm4_tags(void *handle, int columns, char **data, char **column) static int dm4_tags(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
if (data[0]) if (data[0])
taglist_add_tag(&cur_dive->tag_list, data[0]); taglist_add_tag(&state->cur_dive->tag_list, data[0]);
return 0; return 0;
} }
extern int dm4_dive(void *param, int columns, char **data, char **column) static int dm4_dive(void *param, int columns, char **data, char **column)
{ {
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
int i; int i;
int interval, retval = 0; int interval, retval = 0;
sqlite3 *handle = (sqlite3 *)param; struct parser_state *state = (struct parser_state *)param;
sqlite3 *handle = state->sql_handle;
float *profileBlob; float *profileBlob;
unsigned char *tempBlob; unsigned char *tempBlob;
int *pressureBlob; int *pressureBlob;
@ -173,12 +174,12 @@ extern int dm4_dive(void *param, int columns, char **data, char **column)
char get_tags_template[] = "select Text from DiveTag where DiveId = %d"; char get_tags_template[] = "select Text from DiveTag where DiveId = %d";
char get_events[64]; char get_events[64];
dive_start(); dive_start(state);
cur_dive->number = atoi(data[0]); state->cur_dive->number = atoi(data[0]);
cur_dive->when = (time_t)(atol(data[1])); state->cur_dive->when = (time_t)(atol(data[1]));
if (data[2]) if (data[2])
utf8_string(data[2], &cur_dive->notes); utf8_string(data[2], &state->cur_dive->notes);
/* /*
* DM4 stores Duration and DiveTime. It looks like DiveTime is * DM4 stores Duration and DiveTime. It looks like DiveTime is
@ -188,90 +189,90 @@ extern int dm4_dive(void *param, int columns, char **data, char **column)
* DiveTime = data[15] * DiveTime = data[15]
*/ */
if (data[3]) if (data[3])
cur_dive->duration.seconds = atoi(data[3]); state->cur_dive->duration.seconds = atoi(data[3]);
if (data[15]) if (data[15])
cur_dive->dc.duration.seconds = atoi(data[15]); state->cur_dive->dc.duration.seconds = atoi(data[15]);
/* /*
* TODO: the deviceid hash should be calculated here. * TODO: the deviceid hash should be calculated here.
*/ */
settings_start(); settings_start(state);
dc_settings_start(); dc_settings_start(state);
if (data[4]) if (data[4])
utf8_string(data[4], &cur_settings.dc.serial_nr); utf8_string(data[4], &state->cur_settings.dc.serial_nr);
if (data[5]) if (data[5])
utf8_string(data[5], &cur_settings.dc.model); utf8_string(data[5], &state->cur_settings.dc.model);
cur_settings.dc.deviceid = 0xffffffff; state->cur_settings.dc.deviceid = 0xffffffff;
dc_settings_end(); dc_settings_end(state);
settings_end(); settings_end(state);
if (data[6]) if (data[6])
cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[6], NULL, 0) * 1000); state->cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[6], NULL, 0) * 1000);
if (data[8]) if (data[8])
cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8])); state->cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8]));
if (data[9]) if (data[9])
cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9])); state->cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9]));
/* /*
* TODO: handle multiple cylinders * TODO: handle multiple cylinders
*/ */
cylinder_start(); cylinder_start(state);
if (data[22] && atoi(data[22]) > 0) if (data[22] && atoi(data[22]) > 0)
cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[22]); state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar = atoi(data[22]);
else if (data[10] && atoi(data[10]) > 0) else if (data[10] && atoi(data[10]) > 0)
cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[10]); state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar = atoi(data[10]);
if (data[23] && atoi(data[23]) > 0) if (data[23] && atoi(data[23]) > 0)
cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[23])); state->cur_dive->cylinder[state->cur_cylinder_index].end.mbar = (atoi(data[23]));
if (data[11] && atoi(data[11]) > 0) if (data[11] && atoi(data[11]) > 0)
cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[11])); state->cur_dive->cylinder[state->cur_cylinder_index].end.mbar = (atoi(data[11]));
if (data[12]) if (data[12])
cur_dive->cylinder[cur_cylinder_index].type.size.mliter = lrint((strtod_flags(data[12], NULL, 0)) * 1000); state->cur_dive->cylinder[state->cur_cylinder_index].type.size.mliter = lrint((strtod_flags(data[12], NULL, 0)) * 1000);
if (data[13]) if (data[13])
cur_dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = (atoi(data[13])); state->cur_dive->cylinder[state->cur_cylinder_index].type.workingpressure.mbar = (atoi(data[13]));
if (data[20]) if (data[20])
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[20]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = atoi(data[20]) * 10;
if (data[21]) if (data[21])
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[21]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = atoi(data[21]) * 10;
cylinder_end(); cylinder_end(state);
if (data[14]) if (data[14])
cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) * 1000); state->cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) * 1000);
interval = data[16] ? atoi(data[16]) : 0; interval = data[16] ? atoi(data[16]) : 0;
profileBlob = (float *)data[17]; profileBlob = (float *)data[17];
tempBlob = (unsigned char *)data[18]; tempBlob = (unsigned char *)data[18];
pressureBlob = (int *)data[19]; pressureBlob = (int *)data[19];
for (i = 0; interval && i * interval < cur_dive->duration.seconds; i++) { for (i = 0; interval && i * interval < state->cur_dive->duration.seconds; i++) {
sample_start(); sample_start(state);
cur_sample->time.seconds = i * interval; state->cur_sample->time.seconds = i * interval;
if (profileBlob) if (profileBlob)
cur_sample->depth.mm = lrintf(profileBlob[i] * 1000.0f); state->cur_sample->depth.mm = lrintf(profileBlob[i] * 1000.0f);
else else
cur_sample->depth.mm = cur_dive->dc.maxdepth.mm; state->cur_sample->depth.mm = state->cur_dive->dc.maxdepth.mm;
if (data[18] && data[18][0]) if (data[18] && data[18][0])
cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]); state->cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]);
if (data[19] && data[19][0]) if (data[19] && data[19][0])
cur_sample->pressure[0].mbar = pressureBlob[i]; state->cur_sample->pressure[0].mbar = pressureBlob[i];
sample_end(); sample_end(state);
} }
snprintf(get_events, sizeof(get_events) - 1, get_events_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_events_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm4_events, 0, &err); retval = sqlite3_exec(handle, get_events, &dm4_events, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm4_events failed.\n"); fprintf(stderr, "%s", "Database query dm4_events failed.\n");
return 1; return 1;
} }
snprintf(get_events, sizeof(get_events) - 1, get_tags_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_tags_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm4_tags, 0, &err); retval = sqlite3_exec(handle, get_events, &dm4_tags, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm4_tags failed.\n"); fprintf(stderr, "%s", "Database query dm4_tags failed.\n");
return 1; return 1;
} }
dive_end(); dive_end(state);
/* /*
for (i=0; i<columns;++i) { for (i=0; i<columns;++i) {
@ -295,13 +296,18 @@ int parse_dm4_buffer(sqlite3 *handle, const char *url, const char *buffer, int s
int retval; int retval;
char *err = NULL; char *err = NULL;
target_table = table; struct parser_state state;
init_parser_state(&state);
state.target_table = table;
state.sql_handle = handle;
/* StartTime is converted from Suunto's nano seconds to standard /* StartTime is converted from Suunto's nano seconds to standard
* time. We also need epoch, not seconds since year 1. */ * time. We also need epoch, not seconds since year 1. */
char get_dives[] = "select D.DiveId,StartTime/10000000-62135596800,Note,Duration,SourceSerialNumber,Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,D.StartPressure,D.EndPressure,Size,CylinderWorkPressure,SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,Oxygen,Helium,MIX.StartPressure,MIX.EndPressure FROM Dive AS D JOIN DiveMixture AS MIX ON D.DiveId=MIX.DiveId"; char get_dives[] = "select D.DiveId,StartTime/10000000-62135596800,Note,Duration,SourceSerialNumber,Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,D.StartPressure,D.EndPressure,Size,CylinderWorkPressure,SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,Oxygen,Helium,MIX.StartPressure,MIX.EndPressure FROM Dive AS D JOIN DiveMixture AS MIX ON D.DiveId=MIX.DiveId";
retval = sqlite3_exec(handle, get_dives, &dm4_dive, handle, &err); retval = sqlite3_exec(handle, get_dives, &dm4_dive, &state, &err);
free_parser_state(&state);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "Database query failed '%s'.\n", url); fprintf(stderr, "Database query failed '%s'.\n", url);
@ -311,64 +317,65 @@ int parse_dm4_buffer(sqlite3 *handle, const char *url, const char *buffer, int s
return 0; return 0;
} }
extern int dm5_cylinders(void *handle, int columns, char **data, char **column) static int dm5_cylinders(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
cylinder_start(); cylinder_start(state);
if (data[7] && atoi(data[7]) > 0 && atoi(data[7]) < 350000) if (data[7] && atoi(data[7]) > 0 && atoi(data[7]) < 350000)
cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[7]); state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar = atoi(data[7]);
if (data[8] && atoi(data[8]) > 0 && atoi(data[8]) < 350000) if (data[8] && atoi(data[8]) > 0 && atoi(data[8]) < 350000)
cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[8])); state->cur_dive->cylinder[state->cur_cylinder_index].end.mbar = (atoi(data[8]));
if (data[6]) { if (data[6]) {
/* DM5 shows tank size of 12 liters when the actual /* DM5 shows tank size of 12 liters when the actual
* value is 0 (and using metric units). So we just use * value is 0 (and using metric units). So we just use
* the same 12 liters when size is not available */ * the same 12 liters when size is not available */
if (strtod_flags(data[6], NULL, 0) == 0.0 && cur_dive->cylinder[cur_cylinder_index].start.mbar) if (strtod_flags(data[6], NULL, 0) == 0.0 && state->cur_dive->cylinder[state->cur_cylinder_index].start.mbar)
cur_dive->cylinder[cur_cylinder_index].type.size.mliter = 12000; state->cur_dive->cylinder[state->cur_cylinder_index].type.size.mliter = 12000;
else else
cur_dive->cylinder[cur_cylinder_index].type.size.mliter = lrint((strtod_flags(data[6], NULL, 0)) * 1000); state->cur_dive->cylinder[state->cur_cylinder_index].type.size.mliter = lrint((strtod_flags(data[6], NULL, 0)) * 1000);
} }
if (data[2]) if (data[2])
cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[2]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.o2.permille = atoi(data[2]) * 10;
if (data[3]) if (data[3])
cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[3]) * 10; state->cur_dive->cylinder[state->cur_cylinder_index].gasmix.he.permille = atoi(data[3]) * 10;
cylinder_end(); cylinder_end(state);
return 0; return 0;
} }
extern int dm5_gaschange(void *handle, int columns, char **data, char **column) static int dm5_gaschange(void *param, int columns, char **data, char **column)
{ {
UNUSED(handle);
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
struct parser_state *state = (struct parser_state *)param;
event_start(); event_start(state);
if (data[0]) if (data[0])
cur_event.time.seconds = atoi(data[0]); state->cur_event.time.seconds = atoi(data[0]);
if (data[1]) { if (data[1]) {
strcpy(cur_event.name, "gaschange"); strcpy(state->cur_event.name, "gaschange");
cur_event.value = lrint(strtod_flags(data[1], NULL, 0)); state->cur_event.value = lrint(strtod_flags(data[1], NULL, 0));
} }
/* He part of the mix */ /* He part of the mix */
if (data[2]) if (data[2])
cur_event.value += lrint(strtod_flags(data[2], NULL, 0)) << 16; state->cur_event.value += lrint(strtod_flags(data[2], NULL, 0)) << 16;
event_end(); event_end(state);
return 0; return 0;
} }
extern int dm5_dive(void *param, int columns, char **data, char **column) static int dm5_dive(void *param, int columns, char **data, char **column)
{ {
UNUSED(columns); UNUSED(columns);
UNUSED(column); UNUSED(column);
int i; int i;
int tempformat = 0; int tempformat = 0;
int interval, retval = 0, block_size; int interval, retval = 0, block_size;
sqlite3 *handle = (sqlite3 *)param; struct parser_state *state = (struct parser_state *)param;
sqlite3 *handle = state->sql_handle;
unsigned const char *sampleBlob; unsigned const char *sampleBlob;
char *err = NULL; char *err = NULL;
char get_events_template[] = "select * from Mark where DiveId = %d"; char get_events_template[] = "select * from Mark where DiveId = %d";
@ -377,55 +384,55 @@ extern int dm5_dive(void *param, int columns, char **data, char **column)
char get_gaschange_template[] = "select GasChangeTime,Oxygen,Helium from DiveGasChange join DiveMixture on DiveGasChange.DiveMixtureId=DiveMixture.DiveMixtureId where DiveId = %d"; char get_gaschange_template[] = "select GasChangeTime,Oxygen,Helium from DiveGasChange join DiveMixture on DiveGasChange.DiveMixtureId=DiveMixture.DiveMixtureId where DiveId = %d";
char get_events[512]; char get_events[512];
dive_start(); dive_start(state);
cur_dive->number = atoi(data[0]); state->cur_dive->number = atoi(data[0]);
cur_dive->when = (time_t)(atol(data[1])); state->cur_dive->when = (time_t)(atol(data[1]));
if (data[2]) if (data[2])
utf8_string(data[2], &cur_dive->notes); utf8_string(data[2], &state->cur_dive->notes);
if (data[3]) if (data[3])
cur_dive->duration.seconds = atoi(data[3]); state->cur_dive->duration.seconds = atoi(data[3]);
if (data[15]) if (data[15])
cur_dive->dc.duration.seconds = atoi(data[15]); state->cur_dive->dc.duration.seconds = atoi(data[15]);
/* /*
* TODO: the deviceid hash should be calculated here. * TODO: the deviceid hash should be calculated here.
*/ */
settings_start(); settings_start(state);
dc_settings_start(); dc_settings_start(state);
if (data[4]) { if (data[4]) {
utf8_string(data[4], &cur_settings.dc.serial_nr); utf8_string(data[4], &state->cur_settings.dc.serial_nr);
cur_settings.dc.deviceid = atoi(data[4]); state->cur_settings.dc.deviceid = atoi(data[4]);
} }
if (data[5]) if (data[5])
utf8_string(data[5], &cur_settings.dc.model); utf8_string(data[5], &state->cur_settings.dc.model);
dc_settings_end(); dc_settings_end(state);
settings_end(); settings_end(state);
if (data[6]) if (data[6])
cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[6], NULL, 0) * 1000); state->cur_dive->dc.maxdepth.mm = lrint(strtod_flags(data[6], NULL, 0) * 1000);
if (data[8]) if (data[8])
cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8])); state->cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8]));
if (data[9]) if (data[9])
cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9])); state->cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9]));
if (data[4]) { if (data[4]) {
cur_dive->dc.deviceid = atoi(data[4]); state->cur_dive->dc.deviceid = atoi(data[4]);
} }
if (data[5]) if (data[5])
utf8_string(data[5], &cur_dive->dc.model); utf8_string(data[5], &state->cur_dive->dc.model);
snprintf(get_events, sizeof(get_events) - 1, get_cylinders_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_cylinders_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm5_cylinders, 0, &err); retval = sqlite3_exec(handle, get_events, &dm5_cylinders, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm5_cylinders failed.\n"); fprintf(stderr, "%s", "Database query dm5_cylinders failed.\n");
return 1; return 1;
} }
if (data[14]) if (data[14])
cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) / 100); state->cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) / 100);
interval = data[16] ? atoi(data[16]) : 0; interval = data[16] ? atoi(data[16]) : 0;
@ -469,20 +476,20 @@ extern int dm5_dive(void *param, int columns, char **data, char **column)
} }
} }
for (i = 0; interval && sampleBlob && i * interval < cur_dive->duration.seconds; i++) { for (i = 0; interval && sampleBlob && i * interval < state->cur_dive->duration.seconds; i++) {
float *depth = (float *)&sampleBlob[i * block_size + 3]; float *depth = (float *)&sampleBlob[i * block_size + 3];
int32_t pressure = (sampleBlob[i * block_size + 9] << 16) + (sampleBlob[i * block_size + 8] << 8) + sampleBlob[i * block_size + 7]; int32_t pressure = (sampleBlob[i * block_size + 9] << 16) + (sampleBlob[i * block_size + 8] << 8) + sampleBlob[i * block_size + 7];
sample_start(); sample_start(state);
cur_sample->time.seconds = i * interval; state->cur_sample->time.seconds = i * interval;
cur_sample->depth.mm = lrintf(depth[0] * 1000.0f); state->cur_sample->depth.mm = lrintf(depth[0] * 1000.0f);
if (tempformat == 1) { if (tempformat == 1) {
float *temp = (float *)&(sampleBlob[i * block_size + 11]); float *temp = (float *)&(sampleBlob[i * block_size + 11]);
cur_sample->temperature.mkelvin = C_to_mkelvin(*temp); state->cur_sample->temperature.mkelvin = C_to_mkelvin(*temp);
} else { } else {
if ((sampleBlob[i * block_size + 11]) != 0x7F) { if ((sampleBlob[i * block_size + 11]) != 0x7F) {
cur_sample->temperature.mkelvin = C_to_mkelvin(sampleBlob[i * block_size + 11]); state->cur_sample->temperature.mkelvin = C_to_mkelvin(sampleBlob[i * block_size + 11]);
} }
} }
@ -490,8 +497,8 @@ extern int dm5_dive(void *param, int columns, char **data, char **column)
* Limit cylinder pressures to somewhat sensible values * Limit cylinder pressures to somewhat sensible values
*/ */
if (pressure >= 0 && pressure < 350000) if (pressure >= 0 && pressure < 350000)
cur_sample->pressure[0].mbar = pressure; state->cur_sample->pressure[0].mbar = pressure;
sample_end(); sample_end(state);
} }
/* /*
@ -507,44 +514,44 @@ extern int dm5_dive(void *param, int columns, char **data, char **column)
profileBlob = (float *)data[17]; profileBlob = (float *)data[17];
tempBlob = (unsigned char *)data[18]; tempBlob = (unsigned char *)data[18];
pressureBlob = (int *)data[19]; pressureBlob = (int *)data[19];
for (i = 0; interval && i * interval < cur_dive->duration.seconds; i++) { for (i = 0; interval && i * interval < state->cur_dive->duration.seconds; i++) {
sample_start(); sample_start(state);
cur_sample->time.seconds = i * interval; state->cur_sample->time.seconds = i * interval;
if (profileBlob) if (profileBlob)
cur_sample->depth.mm = lrintf(profileBlob[i] * 1000.0f); state->cur_sample->depth.mm = lrintf(profileBlob[i] * 1000.0f);
else else
cur_sample->depth.mm = cur_dive->dc.maxdepth.mm; state->cur_sample->depth.mm = state->cur_dive->dc.maxdepth.mm;
if (data[18] && data[18][0]) if (data[18] && data[18][0])
cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]); state->cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]);
if (data[19] && data[19][0]) if (data[19] && data[19][0])
cur_sample->pressure[0].mbar = pressureBlob[i]; state->cur_sample->pressure[0].mbar = pressureBlob[i];
sample_end(); sample_end(state);
} }
} }
snprintf(get_events, sizeof(get_events) - 1, get_gaschange_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_gaschange_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm5_gaschange, 0, &err); retval = sqlite3_exec(handle, get_events, &dm5_gaschange, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm5_gaschange failed.\n"); fprintf(stderr, "%s", "Database query dm5_gaschange failed.\n");
return 1; return 1;
} }
snprintf(get_events, sizeof(get_events) - 1, get_events_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_events_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm4_events, 0, &err); retval = sqlite3_exec(handle, get_events, &dm4_events, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm4_events failed.\n"); fprintf(stderr, "%s", "Database query dm4_events failed.\n");
return 1; return 1;
} }
snprintf(get_events, sizeof(get_events) - 1, get_tags_template, cur_dive->number); snprintf(get_events, sizeof(get_events) - 1, get_tags_template, state->cur_dive->number);
retval = sqlite3_exec(handle, get_events, &dm4_tags, 0, &err); retval = sqlite3_exec(handle, get_events, &dm4_tags, state, &err);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "%s", "Database query dm4_tags failed.\n"); fprintf(stderr, "%s", "Database query dm4_tags failed.\n");
return 1; return 1;
} }
dive_end(); dive_end(state);
return SQLITE_OK; return SQLITE_OK;
} }
@ -557,13 +564,18 @@ int parse_dm5_buffer(sqlite3 *handle, const char *url, const char *buffer, int s
int retval; int retval;
char *err = NULL; char *err = NULL;
target_table = table; struct parser_state state;
init_parser_state(&state);
state.target_table = table;
state.sql_handle = handle;
/* StartTime is converted from Suunto's nano seconds to standard /* StartTime is converted from Suunto's nano seconds to standard
* time. We also need epoch, not seconds since year 1. */ * time. We also need epoch, not seconds since year 1. */
char get_dives[] = "select DiveId,StartTime/10000000-62135596800,Note,Duration,coalesce(SourceSerialNumber,SerialNumber),Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,StartPressure,EndPressure,'','',SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,'','','','',SampleBlob FROM Dive where Deleted is null"; char get_dives[] = "select DiveId,StartTime/10000000-62135596800,Note,Duration,coalesce(SourceSerialNumber,SerialNumber),Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,StartPressure,EndPressure,'','',SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,'','','','',SampleBlob FROM Dive where Deleted is null";
retval = sqlite3_exec(handle, get_dives, &dm5_dive, handle, &err); retval = sqlite3_exec(handle, get_dives, &dm5_dive, &state, &err);
free_parser_state(&state);
if (retval != SQLITE_OK) { if (retval != SQLITE_OK) {
fprintf(stderr, "Database query failed '%s'.\n", url); fprintf(stderr, "Database query failed '%s'.\n", url);

File diff suppressed because it is too large Load diff

View file

@ -14,37 +14,39 @@
#include "device.h" #include "device.h"
#include "gettext.h" #include "gettext.h"
int metric = 1;
event_allocation_t event_allocation = { .event.deleted = 1 };
struct parser_settings cur_settings;
struct divecomputer *cur_dc = NULL;
struct dive *cur_dive = NULL;
struct dive_site *cur_dive_site = NULL;
location_t cur_location;
dive_trip_t *cur_trip = NULL;
struct sample *cur_sample = NULL;
struct picture *cur_picture = NULL;
bool in_settings = false;
bool in_userid = false;
struct tm cur_tm;
int cur_cylinder_index, cur_ws_index;
int lastcylinderindex, next_o2_sensor;
int o2pressure_sensor;
struct extra_data cur_extra_data;
struct dive_table dive_table; struct dive_table dive_table;
struct dive_table *target_table = NULL;
void init_parser_state(struct parser_state *state)
{
memset(state, 0, sizeof(*state));
state->metric = true;
state->cur_event.deleted = 1;
}
void free_parser_state(struct parser_state *state)
{
free_dive(state->cur_dive);
free_trip(state->cur_trip);
free_dive_site(state->cur_dive_site);
free_picture(state->cur_picture);
free((void *)state->cur_extra_data.key);
free((void *)state->cur_extra_data.value);
free((void *)state->cur_settings.dc.nickname);
free((void *)state->cur_settings.dc.model);
free((void *)state->cur_settings.dc.nickname);
free((void *)state->cur_settings.dc.serial_nr);
free((void *)state->cur_settings.dc.firmware);
free(state->country);
free(state->city);
}
/* /*
* If we don't have an explicit dive computer, * If we don't have an explicit dive computer,
* we use the implicit one that every dive has.. * we use the implicit one that every dive has..
*/ */
struct divecomputer *get_dc(void) struct divecomputer *get_dc(struct parser_state *state)
{ {
return cur_dc ?: &cur_dive->dc; return state->cur_dc ?: &state->cur_dive->dc;
} }
/* Trim a character string by removing leading and trailing white space characters. /* Trim a character string by removing leading and trailing white space characters.
@ -102,48 +104,48 @@ void nonmatch(const char *type, const char *name, char *buffer)
type, name, buffer); type, name, buffer);
} }
void event_start(void) void event_start(struct parser_state *state)
{ {
memset(&cur_event, 0, sizeof(cur_event)); memset(&state->cur_event, 0, sizeof(state->cur_event));
cur_event.deleted = 0; /* Active */ state->cur_event.deleted = 0; /* Active */
} }
void event_end(void) void event_end(struct parser_state *state)
{ {
struct divecomputer *dc = get_dc(); struct divecomputer *dc = get_dc(state);
if (cur_event.type == 123) { if (state->cur_event.type == 123) {
struct picture *pic = alloc_picture(); struct picture *pic = alloc_picture();
pic->filename = strdup(cur_event.name); pic->filename = strdup(state->cur_event.name);
/* theoretically this could fail - but we didn't support multi year offsets */ /* theoretically this could fail - but we didn't support multi year offsets */
pic->offset.seconds = cur_event.time.seconds; pic->offset.seconds = state->cur_event.time.seconds;
dive_add_picture(cur_dive, pic); dive_add_picture(state->cur_dive, pic);
} else { } else {
struct event *ev; struct event *ev;
/* At some point gas change events did not have any type. Thus we need to add /* At some point gas change events did not have any type. Thus we need to add
* one on import, if we encounter the type one missing. * one on import, if we encounter the type one missing.
*/ */
if (cur_event.type == 0 && strcmp(cur_event.name, "gaschange") == 0) if (state->cur_event.type == 0 && strcmp(state->cur_event.name, "gaschange") == 0)
cur_event.type = cur_event.value >> 16 > 0 ? SAMPLE_EVENT_GASCHANGE2 : SAMPLE_EVENT_GASCHANGE; state->cur_event.type = state->cur_event.value >> 16 > 0 ? SAMPLE_EVENT_GASCHANGE2 : SAMPLE_EVENT_GASCHANGE;
ev = add_event(dc, cur_event.time.seconds, ev = add_event(dc, state->cur_event.time.seconds,
cur_event.type, cur_event.flags, state->cur_event.type, state->cur_event.flags,
cur_event.value, cur_event.name); state->cur_event.value, state->cur_event.name);
/* /*
* Older logs might mark the dive to be CCR by having an "SP change" event at time 0:00. Better * Older logs might mark the dive to be CCR by having an "SP change" event at time 0:00. Better
* to mark them being CCR on import so no need for special treatments elsewhere on the code. * to mark them being CCR on import so no need for special treatments elsewhere on the code.
*/ */
if (ev && cur_event.time.seconds == 0 && cur_event.type == SAMPLE_EVENT_PO2 && cur_event.value && dc->divemode==OC) { if (ev && state->cur_event.time.seconds == 0 && state->cur_event.type == SAMPLE_EVENT_PO2 && state->cur_event.value && dc->divemode==OC) {
dc->divemode = CCR; dc->divemode = CCR;
} }
if (ev && event_is_gaschange(ev)) { if (ev && event_is_gaschange(ev)) {
/* See try_to_fill_event() on why the filled-in index is one too big */ /* See try_to_fill_event() on why the filled-in index is one too big */
ev->gas.index = cur_event.gas.index-1; ev->gas.index = state->cur_event.gas.index-1;
if (cur_event.gas.mix.o2.permille || cur_event.gas.mix.he.permille) if (state->cur_event.gas.mix.o2.permille || state->cur_event.gas.mix.he.permille)
ev->gas.mix = cur_event.gas.mix; ev->gas.mix = state->cur_event.gas.mix;
} }
} }
cur_event.deleted = 1; /* No longer active */ state->cur_event.deleted = 1; /* No longer active */
} }
/* /*
@ -158,156 +160,156 @@ void event_end(void)
* to make a dive valid, but if it has no location, no date and no * to make a dive valid, but if it has no location, no date and no
* samples I'm pretty sure it's useless. * samples I'm pretty sure it's useless.
*/ */
bool is_dive(void) bool is_dive(struct parser_state *state)
{ {
return cur_dive && return state->cur_dive &&
(cur_dive->dive_site_uuid || cur_dive->when || cur_dive->dc.samples); (state->cur_dive->dive_site_uuid || state->cur_dive->when || state->cur_dive->dc.samples);
} }
void reset_dc_info(struct divecomputer *dc) void reset_dc_info(struct divecomputer *dc, struct parser_state *state)
{ {
/* WARN: reset dc info does't touch the dc? */ /* WARN: reset dc info does't touch the dc? */
UNUSED(dc); UNUSED(dc);
lastcylinderindex = 0; state->lastcylinderindex = 0;
} }
void reset_dc_settings(void) void reset_dc_settings(struct parser_state *state)
{ {
free((void *)cur_settings.dc.model); free((void *)state->cur_settings.dc.model);
free((void *)cur_settings.dc.nickname); free((void *)state->cur_settings.dc.nickname);
free((void *)cur_settings.dc.serial_nr); free((void *)state->cur_settings.dc.serial_nr);
free((void *)cur_settings.dc.firmware); free((void *)state->cur_settings.dc.firmware);
cur_settings.dc.model = NULL; state->cur_settings.dc.model = NULL;
cur_settings.dc.nickname = NULL; state->cur_settings.dc.nickname = NULL;
cur_settings.dc.serial_nr = NULL; state->cur_settings.dc.serial_nr = NULL;
cur_settings.dc.firmware = NULL; state->cur_settings.dc.firmware = NULL;
cur_settings.dc.deviceid = 0; state->cur_settings.dc.deviceid = 0;
} }
void settings_start(void) void settings_start(struct parser_state *state)
{ {
in_settings = true; state->in_settings = true;
} }
void settings_end(void) void settings_end(struct parser_state *state)
{ {
in_settings = false; state->in_settings = false;
} }
void dc_settings_start(void) void dc_settings_start(struct parser_state *state)
{ {
reset_dc_settings(); reset_dc_settings(state);
} }
void dc_settings_end(void) void dc_settings_end(struct parser_state *state)
{ {
create_device_node(cur_settings.dc.model, cur_settings.dc.deviceid, cur_settings.dc.serial_nr, create_device_node(state->cur_settings.dc.model, state->cur_settings.dc.deviceid, state->cur_settings.dc.serial_nr,
cur_settings.dc.firmware, cur_settings.dc.nickname); state->cur_settings.dc.firmware, state->cur_settings.dc.nickname);
reset_dc_settings(); reset_dc_settings(state);
} }
void dive_site_start(void) void dive_site_start(struct parser_state *state)
{ {
if (cur_dive_site) if (state->cur_dive_site)
return; return;
cur_dive_site = calloc(1, sizeof(struct dive_site)); state->cur_dive_site = calloc(1, sizeof(struct dive_site));
} }
void dive_site_end(void) void dive_site_end(struct parser_state *state)
{ {
if (!cur_dive_site) if (!state->cur_dive_site)
return; return;
if (cur_dive_site->taxonomy.nr == 0) { if (state->cur_dive_site->taxonomy.nr == 0) {
free(cur_dive_site->taxonomy.category); free(state->cur_dive_site->taxonomy.category);
cur_dive_site->taxonomy.category = NULL; state->cur_dive_site->taxonomy.category = NULL;
} }
if (cur_dive_site->uuid) { if (state->cur_dive_site->uuid) {
struct dive_site *ds = alloc_or_get_dive_site(cur_dive_site->uuid); struct dive_site *ds = alloc_or_get_dive_site(state->cur_dive_site->uuid);
merge_dive_site(ds, cur_dive_site); merge_dive_site(ds, state->cur_dive_site);
if (verbose > 3) if (verbose > 3)
printf("completed dive site uuid %x8 name {%s}\n", ds->uuid, ds->name); printf("completed dive site uuid %x8 name {%s}\n", ds->uuid, ds->name);
} }
free_dive_site(cur_dive_site); free_dive_site(state->cur_dive_site);
cur_dive_site = NULL; state->cur_dive_site = NULL;
} }
// now we need to add the code to parse the parts of the divesite enry // now we need to add the code to parse the parts of the divesite enry
void dive_start(void) void dive_start(struct parser_state *state)
{ {
if (cur_dive) if (state->cur_dive)
return; return;
cur_dive = alloc_dive(); state->cur_dive = alloc_dive();
reset_dc_info(&cur_dive->dc); reset_dc_info(&state->cur_dive->dc, state);
memset(&cur_tm, 0, sizeof(cur_tm)); memset(&state->cur_tm, 0, sizeof(state->cur_tm));
if (cur_trip) { if (state->cur_trip) {
add_dive_to_trip(cur_dive, cur_trip); add_dive_to_trip(state->cur_dive, state->cur_trip);
cur_dive->tripflag = IN_TRIP; state->cur_dive->tripflag = IN_TRIP;
} }
o2pressure_sensor = 1; state->o2pressure_sensor = 1;
} }
void dive_end(void) void dive_end(struct parser_state *state)
{ {
if (!cur_dive) if (!state->cur_dive)
return; return;
if (!is_dive()) if (!is_dive(state))
free_dive(cur_dive); free_dive(state->cur_dive);
else else
record_dive_to_table(cur_dive, target_table); record_dive_to_table(state->cur_dive, state->target_table);
cur_dive = NULL; state->cur_dive = NULL;
cur_dc = NULL; state->cur_dc = NULL;
cur_location.lat.udeg = 0; state->cur_location.lat.udeg = 0;
cur_location.lon.udeg = 0; state->cur_location.lon.udeg = 0;
cur_cylinder_index = 0; state->cur_cylinder_index = 0;
cur_ws_index = 0; state->cur_ws_index = 0;
} }
void trip_start(void) void trip_start(struct parser_state *state)
{ {
if (cur_trip) if (state->cur_trip)
return; return;
dive_end(); dive_end(state);
cur_trip = alloc_trip(); state->cur_trip = alloc_trip();
memset(&cur_tm, 0, sizeof(cur_tm)); memset(&state->cur_tm, 0, sizeof(state->cur_tm));
} }
void trip_end(void) void trip_end(struct parser_state *state)
{ {
if (!cur_trip) if (!state->cur_trip)
return; return;
insert_trip(&cur_trip); insert_trip(&state->cur_trip);
cur_trip = NULL; state->cur_trip = NULL;
} }
void picture_start(void) void picture_start(struct parser_state *state)
{ {
cur_picture = alloc_picture(); state->cur_picture = alloc_picture();
} }
void picture_end(void) void picture_end(struct parser_state *state)
{ {
dive_add_picture(cur_dive, cur_picture); dive_add_picture(state->cur_dive, state->cur_picture);
cur_picture = NULL; state->cur_picture = NULL;
} }
void cylinder_start(void) void cylinder_start(struct parser_state *state)
{ {
} }
void cylinder_end(void) void cylinder_end(struct parser_state *state)
{ {
cur_cylinder_index++; state->cur_cylinder_index++;
} }
void ws_start(void) void ws_start(struct parser_state *state)
{ {
} }
void ws_end(void) void ws_end(struct parser_state *state)
{ {
cur_ws_index++; state->cur_ws_index++;
} }
/* /*
@ -328,9 +330,9 @@ void ws_end(void)
* or the second cylinder depending on what isn't an * or the second cylinder depending on what isn't an
* oxygen cylinder. * oxygen cylinder.
*/ */
void sample_start(void) void sample_start(struct parser_state *state)
{ {
struct divecomputer *dc = get_dc(); struct divecomputer *dc = get_dc(state);
struct sample *sample = prepare_sample(dc); struct sample *sample = prepare_sample(dc);
if (sample != dc->sample) { if (sample != dc->sample) {
@ -338,28 +340,28 @@ void sample_start(void)
sample->pressure[0].mbar = 0; sample->pressure[0].mbar = 0;
sample->pressure[1].mbar = 0; sample->pressure[1].mbar = 0;
} else { } else {
sample->sensor[0] = !o2pressure_sensor; sample->sensor[0] = !state->o2pressure_sensor;
sample->sensor[1] = o2pressure_sensor; sample->sensor[1] = state->o2pressure_sensor;
} }
cur_sample = sample; state->cur_sample = sample;
next_o2_sensor = 0; state->next_o2_sensor = 0;
} }
void sample_end(void) void sample_end(struct parser_state *state)
{ {
if (!cur_dive) if (!state->cur_dive)
return; return;
finish_sample(get_dc()); finish_sample(get_dc(state));
cur_sample = NULL; state->cur_sample = NULL;
} }
void divecomputer_start(void) void divecomputer_start(struct parser_state *state)
{ {
struct divecomputer *dc; struct divecomputer *dc;
/* Start from the previous dive computer */ /* Start from the previous dive computer */
dc = &cur_dive->dc; dc = &state->cur_dive->dc;
while (dc->next) while (dc->next)
dc = dc->next; dc = dc->next;
@ -373,25 +375,25 @@ void divecomputer_start(void)
} }
/* .. this is the one we'll use */ /* .. this is the one we'll use */
cur_dc = dc; state->cur_dc = dc;
reset_dc_info(dc); reset_dc_info(dc, state);
} }
void divecomputer_end(void) void divecomputer_end(struct parser_state *state)
{ {
if (!cur_dc->when) if (!state->cur_dc->when)
cur_dc->when = cur_dive->when; state->cur_dc->when = state->cur_dive->when;
cur_dc = NULL; state->cur_dc = NULL;
} }
void userid_start(void) void userid_start(struct parser_state *state)
{ {
in_userid = true; state->in_userid = true;
} }
void userid_stop(void) void userid_stop(struct parser_state *state)
{ {
in_userid = false; state->in_userid = false;
} }
/* /*
@ -409,7 +411,7 @@ void utf8_string(char *buffer, void *_res)
*res = strdup(buffer); *res = strdup(buffer);
} }
void add_dive_site(char *ds_name, struct dive *dive) void add_dive_site(char *ds_name, struct dive *dive, struct parser_state *state)
{ {
char *buffer = ds_name; char *buffer = ds_name;
char *to_free = NULL; char *to_free = NULL;
@ -441,9 +443,9 @@ void add_dive_site(char *ds_name, struct dive *dive)
} else { } else {
dive->dive_site_uuid = create_dive_site(buffer, dive->when); dive->dive_site_uuid = create_dive_site(buffer, dive->when);
struct dive_site *newds = get_dive_site_by_uuid(dive->dive_site_uuid); struct dive_site *newds = get_dive_site_by_uuid(dive->dive_site_uuid);
if (has_location(&cur_location)) { if (has_location(&state->cur_location)) {
// we started this uuid with GPS data, so lets use those // we started this uuid with GPS data, so lets use those
newds->location = cur_location; newds->location = state->cur_location;
} else { } else {
newds->location = ds->location; newds->location = ds->location;
} }

View file

@ -9,20 +9,9 @@ typedef union {
char allocation[sizeof(struct event) + MAX_EVENT_NAME]; char allocation[sizeof(struct event) + MAX_EVENT_NAME];
} event_allocation_t; } event_allocation_t;
extern event_allocation_t event_allocation;
#define cur_event event_allocation.event
/* /*
* Dive info as it is being built up.. * Dive info as it is being built up..
*/ */
extern struct divecomputer *cur_dc;
extern struct dive *cur_dive;
extern struct dive_site *cur_dive_site;
extern location_t cur_location;
extern dive_trip_t *cur_trip;
extern struct sample *cur_sample;
extern struct picture *cur_picture;
struct parser_settings { struct parser_settings {
struct { struct {
@ -31,66 +20,94 @@ struct parser_settings {
const char *nickname, *serial_nr, *firmware; const char *nickname, *serial_nr, *firmware;
} dc; } dc;
}; };
extern struct parser_settings cur_settings;
extern bool in_settings;
extern bool in_userid;
extern struct tm cur_tm;
extern int cur_cylinder_index, cur_ws_index;
extern int lastcylinderindex, next_o2_sensor;
extern int o2pressure_sensor;
extern struct extra_data cur_extra_data;
enum import_source { enum import_source {
UNKNOWN, UNKNOWN,
LIBDIVECOMPUTER, LIBDIVECOMPUTER,
DIVINGLOG, DIVINGLOG,
UDDF, UDDF,
} import_source; };
/*
* parser_state is the state needed by the parser(s). It is initialized
* with init_parser_state() and resources are freed with free_parser_state().
* "owning" marks pointers to objects that are freed in free_parser_state().
* In contrast, "non-owning" marks pointers to objects that are owned
* by other data-structures.
*/
struct parser_state {
bool metric;
struct parser_settings cur_settings;
enum import_source import_source;
struct divecomputer *cur_dc; /* non-owning */
struct dive *cur_dive; /* owning */
struct dive_site *cur_dive_site; /* owning */
location_t cur_location;
dive_trip_t *cur_trip; /* owning */
struct sample *cur_sample; /* non-owning */
struct picture *cur_picture; /* owning */
char *country, *city; /* owning */
bool in_settings;
bool in_userid;
struct tm cur_tm;
int cur_cylinder_index, cur_ws_index;
int lastcylinderindex, next_o2_sensor;
int o2pressure_sensor;
struct extra_data cur_extra_data;
struct units xml_parsing_units;
struct dive_table *target_table; /* non-owning */
sqlite3 *sql_handle; /* for SQL based parsers */
event_allocation_t event_allocation;
};
#define cur_event event_allocation.event
void init_parser_state(struct parser_state *state);
void free_parser_state(struct parser_state *state);
/* the dive table holds the overall dive list; target table points at /* the dive table holds the overall dive list; target table points at
* the table we are currently filling */ * the table we are currently filling */
extern struct dive_table dive_table; extern struct dive_table dive_table;
extern struct dive_table *target_table;
extern int metric;
int trimspace(char *buffer); int trimspace(char *buffer);
void start_match(const char *type, const char *name, char *buffer); void start_match(const char *type, const char *name, char *buffer);
void nonmatch(const char *type, const char *name, char *buffer); void nonmatch(const char *type, const char *name, char *buffer);
void event_start(void); void event_start(struct parser_state *state);
void event_end(void); void event_end(struct parser_state *state);
struct divecomputer *get_dc(void); struct divecomputer *get_dc(struct parser_state *state);
bool is_dive(void); bool is_dive(struct parser_state *state);
void reset_dc_info(struct divecomputer *dc); void reset_dc_info(struct divecomputer *dc, struct parser_state *state);
void reset_dc_settings(void); void reset_dc_settings(struct parser_state *state);
void settings_start(void); void settings_start(struct parser_state *state);
void settings_end(void); void settings_end(struct parser_state *state);
void dc_settings_start(void); void dc_settings_start(struct parser_state *state);
void dc_settings_end(void); void dc_settings_end(struct parser_state *state);
void dive_site_start(void); void dive_site_start(struct parser_state *state);
void dive_site_end(void); void dive_site_end(struct parser_state *state);
void dive_start(void); void dive_start(struct parser_state *state);
void dive_end(void); void dive_end(struct parser_state *state);
void trip_start(void); void trip_start(struct parser_state *state);
void trip_end(void); void trip_end(struct parser_state *state);
void picture_start(void); void picture_start(struct parser_state *state);
void picture_end(void); void picture_end(struct parser_state *state);
void cylinder_start(void); void cylinder_start(struct parser_state *state);
void cylinder_end(void); void cylinder_end(struct parser_state *state);
void ws_start(void); void ws_start(struct parser_state *state);
void ws_end(void); void ws_end(struct parser_state *state);
void sample_start(void); void sample_start(struct parser_state *state);
void sample_end(void); void sample_end(struct parser_state *state);
void divecomputer_start(void); void divecomputer_start(struct parser_state *state);
void divecomputer_end(void); void divecomputer_end(struct parser_state *state);
void userid_start(void); void userid_start(struct parser_state *state);
void userid_stop(void); void userid_stop(struct parser_state *state);
void utf8_string(char *buffer, void *_res); void utf8_string(char *buffer, void *_res);
void add_dive_site(char *ds_name, struct dive *dive); void add_dive_site(char *ds_name, struct dive *dive, struct parser_state *state);
int atoi_n(char *ptr, unsigned int len); int atoi_n(char *ptr, unsigned int len);
#endif #endif