asterisk/res/res_geolocation/geoloc_gml.c

368 lines
12 KiB
C

/*
* Copyright (C) 2022, Sangoma Technologies Corporation
*
* George Joseph <gjoseph@sangoma.com>
*
* See http://www.asterisk.org for more information about
* the Asterisk project. Please do not directly contact
* any of the maintainers of this project for assistance;
* the project provides a web site, mailing lists and IRC
* channels for your use.
*
* This program is free software, distributed under the terms of
* the GNU General Public License Version 2. See the LICENSE file
* at the top of the source tree.
*/
#include "asterisk.h"
#include "asterisk/config.h"
#include "asterisk/cli.h"
#include "asterisk/res_geolocation.h"
#include "geoloc_private.h"
#if 1 //not used yet.
enum geoloc_shape_attrs {
GEOLOC_SHAPE_ATTR_POS = 0,
GEOLOC_SHAPE_ATTR_POS3D,
GEOLOC_SHAPE_ATTR_RADIUS,
GEOLOC_SHAPE_ATTR_SEMI_MAJOR_AXIS,
GEOLOC_SHAPE_ATTR_SEMI_MINOR_AXIS,
GEOLOC_SHAPE_ATTR_VERTICAL_AXIS,
GEOLOC_SHAPE_ATTR_HEIGHT,
GEOLOC_SHAPE_ATTR_ORIENTATION,
GEOLOC_SHAPE_ATTR_ORIENTATION_UOM,
GEOLOC_SHAPE_ATTR_INNER_RADIUS,
GEOLOC_SHAPE_ATTR_OUTER_RADIUS,
GEOLOC_SHAPE_ATTR_STARTING_ANGLE,
GEOLOC_SHAPE_ATTR_OPENING_ANGLE,
GEOLOC_SHAPE_ATTR_ANGLE_UOM,
};
struct geoloc_gml_attr_def {
enum geoloc_shape_attrs attr;
const char *name;
int (*validator)(const char *value);
int (*transformer)(struct ast_variable *value);
};
struct geoloc_gml_attr_def gml_attr_defs[] = {
{ GEOLOC_SHAPE_ATTR_POS, "pos", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_POS3D,"pos3d", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_RADIUS,"radius", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_SEMI_MAJOR_AXIS,"semiMajorAxis", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_SEMI_MINOR_AXIS,"semiMinorAxis", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_VERTICAL_AXIS,"verticalAxis", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_HEIGHT,"height", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_ORIENTATION,"orientation", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_ORIENTATION_UOM,"orientation_uom", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_INNER_RADIUS,"innerRadius", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_OUTER_RADIUS,"outerRadius", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_STARTING_ANGLE,"startingAngle", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_OPENING_ANGLE,"openingAngle", NULL, NULL},
{ GEOLOC_SHAPE_ATTR_ANGLE_UOM,"angle_uom", NULL, NULL},
};
#endif //not used yet.
struct geoloc_gml_attr {
const char *attribute;
int min_required;
int max_allowed;
int (*validator)(const char *value);
};
struct geoloc_gml_shape_def {
const char *shape_type;
struct geoloc_gml_attr required_attributes[8];
};
static int pos_validator(const char *value)
{
float lat;
float lon;
return (sscanf(value, "%f %f", &lat, &lon) == 2);
}
static int pos3d_validator(const char *value)
{
float lat;
float lon;
float alt;
return (sscanf(value, "%f %f %f", &lat, &lon, &alt) == 3);
}
static int float_validator(const char *value)
{
float val;
return (sscanf(value, "%f", &val) == 1);
}
static int uom_validator(const char *value)
{
return (ast_strings_equal(value, "degrees") || ast_strings_equal(value, "radians"));
}
static struct geoloc_gml_shape_def gml_shape_defs[8] = {
{ "Point", { {"pos", 1, 1, pos_validator}, {NULL, -1, -1} }},
{ "Polygon", { {"pos", 3, -1, pos_validator}, {NULL, -1, -1} }},
{ "Circle", { {"pos", 1, 1, pos_validator}, {"radius", 1, 1, float_validator},{NULL, -1, -1}}},
{ "Ellipse", { {"pos", 1, 1, pos_validator}, {"semiMajorAxis", 1, 1, float_validator},
{"semiMinorAxis", 1, 1, float_validator}, {"orientation", 1, 1, float_validator},
{"orientation_uom", 1, 1, uom_validator}, {NULL, -1, -1} }},
{ "ArcBand", { {"pos", 1, 1, pos_validator}, {"innerRadius", 1, 1, float_validator},
{"outerRadius", 1, 1, float_validator}, {"startAngle", 1, 1, float_validator},
{"startAngle_uom", 1, 1, uom_validator}, {"openingAngle", 1, 1, float_validator},
{"openingAngle_uom", 1, 1, uom_validator}, {NULL, -1, -1} }},
{ "Sphere", { {"pos3d", 1, 1, pos3d_validator}, {"radius", 1, 1, float_validator}, {NULL, -1, -1} }},
{ "Ellipse", { {"pos3d", 1, 1, pos3d_validator}, {"semiMajorAxis", 1, 1, float_validator},
{"semiMinorAxis", 1, 1, float_validator}, {"verticalAxis", 1, 1, float_validator},
{"orientation", 1, 1, float_validator}, {"orientation_uom", 1, 1, uom_validator}, {NULL, -1, -1} }},
{ "Prism", { {"pos3d", 3, -1, pos_validator}, {"height", 1, 1, float_validator}, {NULL, -1, -1} }},
};
enum ast_geoloc_validate_result ast_geoloc_gml_validate_varlist(const struct ast_variable *varlist,
const char **result)
{
int def_index = -1;
const struct ast_variable *var;
int i;
const char *shape_type = ast_variable_find_in_list(varlist, "shape");
if (!shape_type) {
return AST_GEOLOC_VALIDATE_MISSING_SHAPE;
}
for (i = 0; i < ARRAY_LEN(gml_shape_defs); i++) {
if (ast_strings_equal(gml_shape_defs[i].shape_type, shape_type)) {
def_index = i;
}
}
if (def_index < 0) {
return AST_GEOLOC_VALIDATE_INVALID_SHAPE;
}
for (var = varlist; var; var = var->next) {
int vname_index = -1;
if (ast_strings_equal("shape", var->name)) {
continue;
}
for (i = 0; i < ARRAY_LEN(gml_shape_defs[def_index].required_attributes); i++) {
if (gml_shape_defs[def_index].required_attributes[i].attribute == NULL) {
break;
}
if (ast_strings_equal(gml_shape_defs[def_index].required_attributes[i].attribute, var->name)) {
vname_index = i;
break;
}
}
if (vname_index < 0) {
*result = var->name;
return AST_GEOLOC_VALIDATE_INVALID_VARNAME;
}
if (!gml_shape_defs[def_index].required_attributes[vname_index].validator(var->value)) {
*result = var->name;
return AST_GEOLOC_VALIDATE_INVALID_VALUE;
}
}
for (i = 0; i < ARRAY_LEN(gml_shape_defs[def_index].required_attributes); i++) {
int count = 0;
if (gml_shape_defs[def_index].required_attributes[i].attribute == NULL) {
break;
}
for (var = varlist; var; var = var->next) {
if (ast_strings_equal(gml_shape_defs[def_index].required_attributes[i].attribute, var->name)) {
count++;
}
}
if (count < gml_shape_defs[def_index].required_attributes[i].min_required) {
*result = gml_shape_defs[def_index].required_attributes[i].attribute;
return AST_GEOLOC_VALIDATE_NOT_ENOUGH_VARNAMES;
}
if (gml_shape_defs[def_index].required_attributes[i].max_allowed > 0 &&
count > gml_shape_defs[def_index].required_attributes[i].max_allowed) {
*result = gml_shape_defs[def_index].required_attributes[i].attribute;
return AST_GEOLOC_VALIDATE_TOO_MANY_VARNAMES;
}
}
return AST_GEOLOC_VALIDATE_SUCCESS;
}
static char *handle_gml_show(struct ast_cli_entry *e, int cmd, struct ast_cli_args *a)
{
int i;
switch (cmd) {
case CLI_INIT:
e->command = "geoloc show gml_shape_defs";
e->usage =
"Usage: geoloc show gml_shape_defs\n"
" Show the GML Shape definitions.\n";
return NULL;
case CLI_GENERATE:
return NULL;
}
ast_cli(a->fd, "%-16s %-32s\n", "Shape", "Attributes name(min,max)");
ast_cli(a->fd, "================ ===============================\n");
for (i = 0; i < ARRAY_LEN(gml_shape_defs); i++) {
int j;
ast_cli(a->fd, "%-16s", gml_shape_defs[i].shape_type);
for (j = 0; j < ARRAY_LEN(gml_shape_defs[i].required_attributes); j++) {
if (gml_shape_defs[i].required_attributes[j].attribute == NULL) {
break;
}
if (gml_shape_defs[i].required_attributes[j].max_allowed >= 0) {
ast_cli(a->fd, " %s(%d,%d)", gml_shape_defs[i].required_attributes[j].attribute,
gml_shape_defs[i].required_attributes[j].min_required,
gml_shape_defs[i].required_attributes[j].max_allowed);
} else {
ast_cli(a->fd, " %s(%d,unl)", gml_shape_defs[i].required_attributes[j].attribute,
gml_shape_defs[i].required_attributes[j].min_required);
}
}
ast_cli(a->fd, "\n");
}
ast_cli(a->fd, "\n");
return CLI_SUCCESS;
}
static struct ast_cli_entry geoloc_gml_cli[] = {
AST_CLI_DEFINE(handle_gml_show, "Show the GML Shape definitions"),
};
struct ast_xml_node *geoloc_gml_list_to_xml(const struct ast_variable *resolved_location,
const char *ref_string)
{
const char *shape;
char *crs;
struct ast_variable *var;
struct ast_xml_node *gml_node;
struct ast_xml_node *child_node;
int rc = 0;
SCOPE_ENTER(3, "%s", ref_string);
if (!resolved_location) {
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: resolved_location was NULL\n",
ref_string);
}
shape = ast_variable_find_in_list(resolved_location, "shape");
if (ast_strlen_zero(shape)) {
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: There's no 'shape' parameter\n",
ref_string);
}
crs = (char *)ast_variable_find_in_list(resolved_location, "crs");
if (ast_strlen_zero(crs)) {
crs = "2d";
}
gml_node = ast_xml_new_node(shape);
if (!gml_node) {
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Unable to create '%s' XML node\n", shape, ref_string);
}
rc = ast_xml_set_attribute(gml_node, "crs", crs);
if (rc != 0) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Unable to create 'crs' XML attribute\n", ref_string);
}
for (var = (struct ast_variable *)resolved_location; var; var = var->next) {
RAII_VAR(char *, value, NULL, ast_free);
char *uom = NULL;
if (ast_strings_equal(var->name, "shape") || ast_strings_equal(var->name, "crs")) {
continue;
}
value = ast_strdup(var->value);
if (ast_strings_equal(var->name, "orientation") || ast_strings_equal(var->name, "startAngle")
|| ast_strings_equal(var->name, "openingAngle")) {
char *a = NULL;
char *junk = NULL;
float angle;
uom = value;
/* 'a' should now be the angle and 'uom' should be the uom */
a = strsep(&uom, " ");
angle = strtof(a, &junk);
/*
* strtof sets junk to the first non-valid character so if it's
* not empty after the conversion, there were unrecognized
* characters in the angle. It'll point to the NULL terminator
* if angle was completely converted.
*/
if (!ast_strlen_zero(junk)) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: The angle portion of parameter '%s' ('%s') is malformed\n",
ref_string, var->name, var->value);
}
if (ast_strlen_zero(uom)) {
uom = "degrees";
}
if (ast_begins_with(uom, "deg")) {
if (angle > 360.0) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Parameter '%s': '%s' is malformed. "
"Degrees can't be > 360.0\n",
ref_string, var->name, var->value);
}
} else if (ast_begins_with(uom, "rad")) {
if(angle > 100.0) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Parameter '%s': '%s' is malformed. "
"Radians can't be > 100.0\n",
ref_string, var->name, var->value);
}
} else {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Parameter '%s': '%s' is malformed. "
"The unit of measure must be 'deg[rees]' or 'rad[ians]'\n",
ref_string, var->name, var->value);
}
}
child_node = ast_xml_new_child(gml_node, var->name);
if (!child_node) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Unable to create '%s' XML node\n", var->name, ref_string);
}
if (!ast_strlen_zero(uom)) {
rc = ast_xml_set_attribute(child_node, "uom", uom);
if (rc != 0) {
ast_xml_free_node(gml_node);
SCOPE_EXIT_LOG_RTN_VALUE(NULL, LOG_ERROR, "%s: Unable to create 'uom' XML attribute\n", ref_string);
}
}
ast_xml_set_text(child_node, value);
}
SCOPE_EXIT_RTN_VALUE(gml_node, "%s: Done\n", ref_string);
}
int geoloc_gml_unload(void)
{
ast_cli_unregister_multiple(geoloc_gml_cli, ARRAY_LEN(geoloc_gml_cli));
return AST_MODULE_LOAD_SUCCESS;
}
int geoloc_gml_load(void)
{
ast_cli_register_multiple(geoloc_gml_cli, ARRAY_LEN(geoloc_gml_cli));
return AST_MODULE_LOAD_SUCCESS;
}
int geoloc_gml_reload(void)
{
return AST_MODULE_LOAD_SUCCESS;
}