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|
/**
* @file llsdutil.cpp
* @author Phoenix
* @date 2006-05-24
* @brief Implementation of classes, functions, etc, for using structured data.
*
* $LicenseInfo:firstyear=2006&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#include "linden_common.h"
#include "llsdutil.h"
#include <sstream>
#if LL_WINDOWS
# include "llwin32headers.h" // for htonl
#elif LL_LINUX
# include <netinet/in.h>
#elif LL_DARWIN || __FreeBSD__
# include <arpa/inet.h>
#endif
#include "llsdserialize.h"
#include "stringize.h"
#include "is_approx_equal_fraction.h"
#include <map>
#include <set>
#include <boost/range.hpp>
// U32
LLSD ll_sd_from_U32(const U32 val)
{
LLSD::Binary v;
U32 net_order = htonl(val);
v.resize(4);
memcpy(&(v[0]), &net_order, 4); /* Flawfinder: ignore */
return LLSD(v);
}
U32 ll_U32_from_sd(const LLSD& sd)
{
U32 ret;
const LLSD::Binary& v = sd.asBinary();
if (v.size() < 4)
{
return 0;
}
memcpy(&ret, &(v[0]), 4); /* Flawfinder: ignore */
ret = ntohl(ret);
return ret;
}
//U64
LLSD ll_sd_from_U64(const U64 val)
{
LLSD::Binary v;
U32 high, low;
high = (U32)(val >> 32);
low = (U32)val;
high = htonl(high);
low = htonl(low);
v.resize(8);
memcpy(&(v[0]), &high, 4); /* Flawfinder: ignore */
memcpy(&(v[4]), &low, 4); /* Flawfinder: ignore */
return LLSD(v);
}
U64 ll_U64_from_sd(const LLSD& sd)
{
U32 high, low;
const LLSD::Binary& v = sd.asBinary();
if (v.size() < 8)
{
return 0;
}
memcpy(&high, &(v[0]), 4); /* Flawfinder: ignore */
memcpy(&low, &(v[4]), 4); /* Flawfinder: ignore */
high = ntohl(high);
low = ntohl(low);
return ((U64)high) << 32 | low;
}
// IP Address (stored in net order in a U32, so don't need swizzling)
LLSD ll_sd_from_ipaddr(const U32 val)
{
LLSD::Binary v;
v.resize(4);
memcpy(&(v[0]), &val, 4); /* Flawfinder: ignore */
return LLSD(v);
}
U32 ll_ipaddr_from_sd(const LLSD& sd)
{
U32 ret;
const LLSD::Binary& v = sd.asBinary();
if (v.size() < 4)
{
return 0;
}
memcpy(&ret, &(v[0]), 4); /* Flawfinder: ignore */
return ret;
}
// Converts an LLSD binary to an LLSD string
LLSD ll_string_from_binary(const LLSD& sd)
{
const LLSD::Binary& value = sd.asBinary();
std::string str;
str.resize(value.size());
memcpy(&str[0], value.data(), value.size());
return str;
}
// Converts an LLSD string to an LLSD binary
LLSD ll_binary_from_string(const LLSD& sd)
{
LLSD::Binary binary_value;
std::string string_value = sd.asString();
for (const U8 c : string_value)
{
binary_value.push_back(c);
}
binary_value.push_back('\0');
return binary_value;
}
char* ll_print_sd(const LLSD& sd)
{
const U32 bufferSize = 10 * 1024;
static char buffer[bufferSize + 1];
std::ostringstream stream;
//stream.rdbuf()->pubsetbuf(buffer, bufferSize);
stream << LLSDOStreamer<LLSDXMLFormatter>(sd);
stream << std::ends;
strncpy(buffer, stream.str().c_str(), bufferSize);
buffer[bufferSize - 1] = '\0';
return buffer;
}
char* ll_pretty_print_sd_ptr(const LLSD* sd)
{
if (sd)
{
return ll_pretty_print_sd(*sd);
}
return NULL;
}
char* ll_pretty_print_sd(const LLSD& sd)
{
const U32 bufferSize = 100 * 1024;
static char buffer[bufferSize + 1];
std::ostringstream stream;
//stream.rdbuf()->pubsetbuf(buffer, bufferSize);
stream << LLSDOStreamer<LLSDXMLFormatter>(sd, LLSDFormatter::OPTIONS_PRETTY);
stream << std::ends;
strncpy(buffer, stream.str().c_str(), bufferSize);
buffer[bufferSize - 1] = '\0';
return buffer;
}
std::string ll_stream_notation_sd(const LLSD& sd)
{
std::ostringstream stream;
stream << LLSDOStreamer<LLSDNotationFormatter>(sd);
return stream.str();
}
//compares the structure of an LLSD to a template LLSD and stores the
//"valid" values in a 3rd LLSD. Default values pulled from the template
//if the tested LLSD does not contain the key/value pair.
//Excess values in the test LLSD are ignored in the resultant_llsd.
//If the llsd to test has a specific key to a map and the values
//are not of the same type, false is returned or if the LLSDs are not
//of the same value. Ordering of arrays matters
//Otherwise, returns true
bool compare_llsd_with_template(
const LLSD& llsd_to_test,
const LLSD& template_llsd,
LLSD& resultant_llsd)
{
LL_PROFILE_ZONE_SCOPED;
if (
llsd_to_test.isUndefined() &&
template_llsd.isDefined() )
{
resultant_llsd = template_llsd;
return true;
}
else if ( llsd_to_test.type() != template_llsd.type() )
{
resultant_llsd = LLSD();
return false;
}
if ( llsd_to_test.isArray() )
{
//they are both arrays
//we loop over all the items in the template
//verifying that the to_test has a subset (in the same order)
//any shortcoming in the testing_llsd are just taken
//to be the rest of the template
LLSD data;
LLSD::array_const_iterator test_iter;
LLSD::array_const_iterator template_iter;
resultant_llsd = LLSD::emptyArray();
test_iter = llsd_to_test.beginArray();
for (
template_iter = template_llsd.beginArray();
(template_iter != template_llsd.endArray() &&
test_iter != llsd_to_test.endArray());
++template_iter)
{
if ( !compare_llsd_with_template(
*test_iter,
*template_iter,
data) )
{
resultant_llsd = LLSD();
return false;
}
else
{
resultant_llsd.append(data);
}
++test_iter;
}
//so either the test or the template ended
//we do another loop now to the end of the template
//grabbing the default values
for (;
template_iter != template_llsd.endArray();
++template_iter)
{
resultant_llsd.append(*template_iter);
}
}
else if ( llsd_to_test.isMap() )
{
//now we loop over the keys of the two maps
//any excess is taken from the template
//excess is ignored in the test
LLSD value;
LLSD::map_const_iterator template_iter;
resultant_llsd = LLSD::emptyMap();
for (
template_iter = template_llsd.beginMap();
template_iter != template_llsd.endMap();
++template_iter)
{
if ( llsd_to_test.has(template_iter->first) )
{
//the test LLSD has the same key
if ( !compare_llsd_with_template(
llsd_to_test[template_iter->first],
template_iter->second,
value) )
{
resultant_llsd = LLSD();
return false;
}
else
{
resultant_llsd[template_iter->first] = value;
}
}
else
{
//test llsd doesn't have it...take the
//template as default value
resultant_llsd[template_iter->first] =
template_iter->second;
}
}
}
else
{
//of same type...take the test llsd's value
resultant_llsd = llsd_to_test;
}
return true;
}
// filter_llsd_with_template() is a direct clone (copy-n-paste) of
// compare_llsd_with_template with the following differences:
// (1) bool vs BOOL return types
// (2) A map with the key value "*" is a special value and maps any key in the
// test llsd that doesn't have an explicitly matching key in the template.
// (3) The element of an array with exactly one element is taken as a template
// for *all* the elements of the test array. If the template array is of
// different size, compare_llsd_with_template() semantics apply.
bool filter_llsd_with_template(
const LLSD & llsd_to_test,
const LLSD & template_llsd,
LLSD & resultant_llsd)
{
LL_PROFILE_ZONE_SCOPED;
if (llsd_to_test.isUndefined() && template_llsd.isDefined())
{
resultant_llsd = template_llsd;
return true;
}
else if (llsd_to_test.type() != template_llsd.type())
{
resultant_llsd = LLSD();
return false;
}
if (llsd_to_test.isArray())
{
//they are both arrays
//we loop over all the items in the template
//verifying that the to_test has a subset (in the same order)
//any shortcoming in the testing_llsd are just taken
//to be the rest of the template
LLSD data;
LLSD::array_const_iterator test_iter;
LLSD::array_const_iterator template_iter;
resultant_llsd = LLSD::emptyArray();
test_iter = llsd_to_test.beginArray();
if (1 == template_llsd.size())
{
// If the template has a single item, treat it as
// the template for *all* items in the test LLSD.
template_iter = template_llsd.beginArray();
for (; test_iter != llsd_to_test.endArray(); ++test_iter)
{
if (! filter_llsd_with_template(*test_iter, *template_iter, data))
{
resultant_llsd = LLSD();
return false;
}
else
{
resultant_llsd.append(data);
}
}
}
else
{
// Traditional compare_llsd_with_template matching
for (template_iter = template_llsd.beginArray();
template_iter != template_llsd.endArray() &&
test_iter != llsd_to_test.endArray();
++template_iter, ++test_iter)
{
if (! filter_llsd_with_template(*test_iter, *template_iter, data))
{
resultant_llsd = LLSD();
return false;
}
else
{
resultant_llsd.append(data);
}
}
//so either the test or the template ended
//we do another loop now to the end of the template
//grabbing the default values
for (;
template_iter != template_llsd.endArray();
++template_iter)
{
resultant_llsd.append(*template_iter);
}
}
}
else if (llsd_to_test.isMap())
{
resultant_llsd = LLSD::emptyMap();
//now we loop over the keys of the two maps
//any excess is taken from the template
//excess is ignored in the test
// Special tag for wildcarded LLSD map key templates
const LLSD::String wildcard_tag("*");
const bool template_has_wildcard = template_llsd.has(wildcard_tag);
LLSD wildcard_value;
LLSD value;
const LLSD::map_const_iterator template_iter_end(template_llsd.endMap());
for (LLSD::map_const_iterator template_iter(template_llsd.beginMap());
template_iter_end != template_iter;
++template_iter)
{
if (wildcard_tag == template_iter->first)
{
wildcard_value = template_iter->second;
}
else if (llsd_to_test.has(template_iter->first))
{
//the test LLSD has the same key
if (! filter_llsd_with_template(llsd_to_test[template_iter->first],
template_iter->second,
value))
{
resultant_llsd = LLSD();
return false;
}
else
{
resultant_llsd[template_iter->first] = value;
}
}
else if (! template_has_wildcard)
{
// test llsd doesn't have it...take the
// template as default value
resultant_llsd[template_iter->first] = template_iter->second;
}
}
if (template_has_wildcard)
{
LLSD sub_value;
LLSD::map_const_iterator test_iter;
for (test_iter = llsd_to_test.beginMap();
test_iter != llsd_to_test.endMap();
++test_iter)
{
if (resultant_llsd.has(test_iter->first))
{
// Final value has test key, assume more specific
// template matched and we shouldn't modify it again.
continue;
}
else if (! filter_llsd_with_template(test_iter->second,
wildcard_value,
sub_value))
{
// Test value doesn't match wildcarded template
resultant_llsd = LLSD();
return false;
}
else
{
// Test value matches template, add the actuals.
resultant_llsd[test_iter->first] = sub_value;
}
}
}
}
else
{
//of same type...take the test llsd's value
resultant_llsd = llsd_to_test;
}
return true;
}
/*****************************************************************************
* Helpers for llsd_matches()
*****************************************************************************/
// raw data used for LLSD::Type lookup
struct Data
{
LLSD::Type type;
const char* name;
} typedata[] =
{
#define def(type) { LLSD::type, &#type[4] }
def(TypeUndefined),
def(TypeBoolean),
def(TypeInteger),
def(TypeReal),
def(TypeString),
def(TypeUUID),
def(TypeDate),
def(TypeURI),
def(TypeBinary),
def(TypeMap),
def(TypeArray)
#undef def
};
// LLSD::Type lookup class into which we load the above static data
class TypeLookup
{
typedef std::map<LLSD::Type, std::string> MapType;
public:
TypeLookup()
{
LL_PROFILE_ZONE_SCOPED;
for (const Data *di(boost::begin(typedata)), *dend(boost::end(typedata)); di != dend; ++di)
{
mMap[di->type] = di->name;
}
}
std::string lookup(LLSD::Type type) const
{
LL_PROFILE_ZONE_SCOPED;
MapType::const_iterator found = mMap.find(type);
if (found != mMap.end())
{
return found->second;
}
return STRINGIZE("<unknown LLSD type " << type << ">");
}
private:
MapType mMap;
};
// static instance of the lookup class
static const TypeLookup sTypes;
// describe a mismatch; phrasing may want tweaking
const std::string op(" required instead of ");
// llsd_matches() wants to identify specifically where in a complex prototype
// structure the mismatch occurred. This entails passing a prefix string,
// empty for the top-level call. If the prototype contains an array of maps,
// and the mismatch occurs in the second map in a key 'foo', we want to
// decorate the returned string with: "[1]['foo']: etc." On the other hand, we
// want to omit the entire prefix -- including colon -- if the mismatch is at
// top level. This helper accepts the (possibly empty) recursively-accumulated
// prefix string, returning either empty or the original string with colon
// appended.
static std::string colon(const std::string& pfx)
{
if (pfx.empty())
return pfx;
return pfx + ": ";
}
// param type for match_types
typedef std::vector<LLSD::Type> TypeVector;
// The scalar cases in llsd_matches() use this helper. In most cases, we can
// accept not only the exact type specified in the prototype, but also other
// types convertible to the expected type. That implies looping over an array
// of such types. If the actual type doesn't match any of them, we want to
// provide a list of acceptable conversions as well as the exact type, e.g.:
// "Integer (or Boolean, Real, String) required instead of UUID". Both the
// implementation and the calling logic are simplified by separating out the
// expected type from the convertible types.
static std::string match_types(LLSD::Type expect, // prototype.type()
const TypeVector& accept, // types convertible to that type
LLSD::Type actual, // type we're checking
const std::string& pfx) // as for llsd_matches
{
LL_PROFILE_ZONE_SCOPED;
// Trivial case: if the actual type is exactly what we expect, we're good.
if (actual == expect)
return "";
// For the rest of the logic, build up a suitable error string as we go so
// we only have to make a single pass over the list of acceptable types.
// If we detect success along the way, we'll simply discard the partial
// error string.
std::ostringstream out;
out << colon(pfx) << sTypes.lookup(expect);
// If there are any convertible types, append that list.
if (! accept.empty())
{
out << " (";
const char* sep = "or ";
for (TypeVector::const_iterator ai(accept.begin()), aend(accept.end());
ai != aend; ++ai, sep = ", ")
{
// Don't forget to return success if we match any of those types...
if (actual == *ai)
return "";
out << sep << sTypes.lookup(*ai);
}
out << ')';
}
// If we got this far, it's because 'actual' was not one of the acceptable
// types, so we must return an error. 'out' already contains colon(pfx)
// and the formatted list of acceptable types, so just append the mismatch
// phrase and the actual type.
out << op << sTypes.lookup(actual);
return out.str();
}
// see docstring in .h file
std::string llsd_matches(const LLSD& prototype, const LLSD& data, const std::string& pfx)
{
LL_PROFILE_ZONE_SCOPED;
// An undefined prototype means that any data is valid.
// An undefined slot in an array or map prototype means that any data
// may fill that slot.
if (prototype.isUndefined())
return "";
// A prototype array must match a data array with at least as many
// entries. Moreover, every prototype entry must match the
// corresponding data entry.
if (prototype.isArray())
{
if (! data.isArray())
{
return STRINGIZE(colon(pfx) << "Array" << op << sTypes.lookup(data.type()));
}
if (data.size() < prototype.size())
{
return STRINGIZE(colon(pfx) << "Array size " << prototype.size() << op
<< "Array size " << data.size());
}
for (LLSD::Integer i = 0; i < prototype.size(); ++i)
{
std::string match(llsd_matches(prototype[i], data[i], STRINGIZE('[' << i << ']')));
if (! match.empty())
{
return match;
}
}
return "";
}
// A prototype map must match a data map. Every key in the prototype
// must have a corresponding key in the data map; every value in the
// prototype must match the corresponding key's value in the data.
if (prototype.isMap())
{
if (! data.isMap())
{
return STRINGIZE(colon(pfx) << "Map" << op << sTypes.lookup(data.type()));
}
// If there are a number of keys missing from the data, it would be
// frustrating to a coder to discover them one at a time, with a big
// build each time. Enumerate all missing keys.
std::ostringstream out;
out << colon(pfx);
const char* init = "Map missing keys: ";
const char* sep = init;
for (LLSD::map_const_iterator mi = prototype.beginMap(); mi != prototype.endMap(); ++mi)
{
if (! data.has(mi->first))
{
out << sep << mi->first;
sep = ", ";
}
}
// So... are we missing any keys?
if (sep != init)
{
return out.str();
}
// Good, the data block contains all the keys required by the
// prototype. Now match the prototype entries.
for (LLSD::map_const_iterator mi2 = prototype.beginMap(); mi2 != prototype.endMap(); ++mi2)
{
std::string match(llsd_matches(mi2->second, data[mi2->first],
STRINGIZE("['" << mi2->first << "']")));
if (! match.empty())
{
return match;
}
}
return "";
}
// A String prototype can match String, Boolean, Integer, Real, UUID,
// Date and URI, because any of these can be converted to String.
if (prototype.isString())
{
static LLSD::Type accept[] =
{
LLSD::TypeBoolean,
LLSD::TypeInteger,
LLSD::TypeReal,
LLSD::TypeUUID,
LLSD::TypeDate,
LLSD::TypeURI
};
return match_types(prototype.type(),
TypeVector(boost::begin(accept), boost::end(accept)),
data.type(),
pfx);
}
// Boolean, Integer, Real match each other or String. TBD: ensure that
// a String value is numeric.
if (prototype.isBoolean() || prototype.isInteger() || prototype.isReal())
{
static LLSD::Type all[] =
{
LLSD::TypeBoolean,
LLSD::TypeInteger,
LLSD::TypeReal,
LLSD::TypeString
};
// Funny business: shuffle the set of acceptable types to include all
// but the prototype's type. Get the acceptable types in a set.
std::set<LLSD::Type> rest(boost::begin(all), boost::end(all));
// Remove the prototype's type because we pass that separately.
rest.erase(prototype.type());
return match_types(prototype.type(),
TypeVector(rest.begin(), rest.end()),
data.type(),
pfx);
}
// UUID, Date and URI match themselves or String.
if (prototype.isUUID() || prototype.isDate() || prototype.isURI())
{
static LLSD::Type accept[] =
{
LLSD::TypeString
};
return match_types(prototype.type(),
TypeVector(boost::begin(accept), boost::end(accept)),
data.type(),
pfx);
}
// We don't yet know the conversion semantics associated with any new LLSD
// data type that might be added, so until we've been extended to handle
// them, assume it's strict: the new type matches only itself. (This is
// true of Binary, which is why we don't handle that case separately.) Too
// bad LLSD doesn't define isConvertible(Type to, Type from).
return match_types(prototype.type(), TypeVector(), data.type(), pfx);
}
bool llsd_equals(const LLSD& lhs, const LLSD& rhs, int bits)
{
LL_PROFILE_ZONE_SCOPED;
// We're comparing strict equality of LLSD representation rather than
// performing any conversions. So if the types aren't equal, the LLSD
// values aren't equal.
if (lhs.type() != rhs.type())
{
return false;
}
// Here we know both types are equal. Now compare values.
switch (lhs.type())
{
case LLSD::TypeUndefined:
// Both are TypeUndefined. There's nothing more to know.
return true;
case LLSD::TypeReal:
// This is where the 'bits' argument comes in handy. If passed
// explicitly, it means to use is_approx_equal_fraction() to compare.
if (bits >= 0)
{
return is_approx_equal_fraction(lhs.asReal(), rhs.asReal(), bits);
}
// Otherwise we compare bit representations, and the usual caveats
// about comparing floating-point numbers apply. Omitting 'bits' when
// comparing Real values is only useful when we expect identical bit
// representation for a given Real value, e.g. for integer-valued
// Reals.
return (lhs.asReal() == rhs.asReal());
#define COMPARE_SCALAR(type) \
case LLSD::Type##type: \
/* LLSD::URI has operator!=() but not operator==() */ \
/* rely on the optimizer for all others */ \
return (! (lhs.as##type() != rhs.as##type()))
COMPARE_SCALAR(Boolean);
COMPARE_SCALAR(Integer);
COMPARE_SCALAR(String);
COMPARE_SCALAR(UUID);
COMPARE_SCALAR(Date);
COMPARE_SCALAR(URI);
COMPARE_SCALAR(Binary);
#undef COMPARE_SCALAR
case LLSD::TypeArray:
{
LLSD::array_const_iterator
lai(lhs.beginArray()), laend(lhs.endArray()),
rai(rhs.beginArray()), raend(rhs.endArray());
// Compare array elements, walking the two arrays in parallel.
for ( ; lai != laend && rai != raend; ++lai, ++rai)
{
// If any one array element is unequal, the arrays are unequal.
if (! llsd_equals(*lai, *rai, bits))
return false;
}
// Here we've reached the end of one or the other array. They're equal
// only if they're BOTH at end: that is, if they have equal length too.
return (lai == laend && rai == raend);
}
case LLSD::TypeMap:
{
// Build a set of all rhs keys.
std::set<LLSD::String> rhskeys;
for (LLSD::map_const_iterator rmi(rhs.beginMap()), rmend(rhs.endMap());
rmi != rmend; ++rmi)
{
rhskeys.insert(rmi->first);
}
// Now walk all the lhs keys.
for (LLSD::map_const_iterator lmi(lhs.beginMap()), lmend(lhs.endMap());
lmi != lmend; ++lmi)
{
// Try to erase this lhs key from the set of rhs keys. If rhs has
// no such key, the maps are unequal. erase(key) returns count of
// items erased.
if (rhskeys.erase(lmi->first) != 1)
return false;
// Both maps have the current key. Compare values.
if (! llsd_equals(lmi->second, rhs[lmi->first], bits))
return false;
}
// We've now established that all the lhs keys have equal values in
// both maps. The maps are equal unless rhs contains a superset of
// those keys.
return rhskeys.empty();
}
default:
// We expect that every possible type() value is specifically handled
// above. Failing to extend this switch to support a new LLSD type is
// an error that must be brought to the coder's attention.
LL_ERRS("llsd_equals") << "llsd_equals(" << lhs << ", " << rhs << ", " << bits << "): "
"unknown type " << lhs.type() << LL_ENDL;
return false; // pacify the compiler
}
}
/*****************************************************************************
* llsd::drill()
*****************************************************************************/
namespace llsd
{
LLSD& drill_ref(LLSD& blob, const LLSD& rawPath)
{
LL_PROFILE_ZONE_SCOPED;
// Treat rawPath uniformly as an array. If it's not already an array,
// store it as the only entry in one. (But let's say Undefined means an
// empty array.)
LLSD path;
if (rawPath.isArray() || rawPath.isUndefined())
{
path = rawPath;
}
else
{
path.append(rawPath);
}
// Need to indicate a current destination -- but that current destination
// must change as we step through the path array. Where normally we'd use
// an LLSD& to capture a subscripted LLSD lvalue, this time we must
// instead use a pointer -- since it must be reassigned.
// Start by pointing to the input blob exactly as is.
LLSD* located{&blob};
// Extract the element of interest by walking path. Use an explicit index
// so that, in case of a bogus type in path, we can identify the specific
// path entry that's bad.
for (LLSD::Integer i = 0; i < path.size(); ++i)
{
LL_PROFILE_ZONE_NUM(i);
const LLSD& key{path[i]};
if (key.isString())
{
// a string path element is a map key
located = &((*located)[key.asString()]);
}
else if (key.isInteger())
{
// an integer path element is an array index
located = &((*located)[key.asInteger()]);
}
else
{
// What do we do with Real or Array or Map or ...?
// As it's a coder error -- not a user error -- rub the coder's
// face in it so it gets fixed.
LL_ERRS("llsdutil") << "drill(" << blob << ", " << rawPath
<< "): path[" << i << "] bad type "
<< sTypes.lookup(key.type()) << LL_ENDL;
}
}
// dereference the pointer to return a reference to the element we found
return *located;
}
LLSD drill(const LLSD& blob, const LLSD& path)
{
LL_PROFILE_ZONE_SCOPED;
// drill_ref() does exactly what we want. Temporarily cast away
// const-ness and use that.
return drill_ref(const_cast<LLSD&>(blob), path);
}
} // namespace llsd
// Construct a deep partial clone of of an LLSD object. primitive types share
// references, however maps, arrays and binary objects are duplicated. An optional
// filter may be include to exclude/include keys in a map.
LLSD llsd_clone(LLSD value, LLSD filter)
{
LL_PROFILE_ZONE_SCOPED;
LLSD clone;
bool has_filter(filter.isMap());
switch (value.type())
{
case LLSD::TypeMap:
clone = LLSD::emptyMap();
for (LLSD::map_const_iterator itm = value.beginMap(); itm != value.endMap(); ++itm)
{
if (has_filter)
{
if (filter.has((*itm).first))
{
if (!filter[(*itm).first].asBoolean())
continue;
}
else if (filter.has("*"))
{
if (!filter["*"].asBoolean())
continue;
}
else
{
continue;
}
}
clone[(*itm).first] = llsd_clone((*itm).second, filter);
}
break;
case LLSD::TypeArray:
clone = LLSD::emptyArray();
for (LLSD::array_const_iterator ita = value.beginArray(); ita != value.endArray(); ++ita)
{
clone.append(llsd_clone(*ita, filter));
}
break;
case LLSD::TypeBinary:
{
clone = LLSD::Binary(value.asBinary().begin(), value.asBinary().end());
break;
}
default:
clone = value;
}
return clone;
}
LLSD llsd_shallow(LLSD value, LLSD filter)
{
LLSD shallow;
bool has_filter(filter.isMap());
if (value.isMap())
{
shallow = LLSD::emptyMap();
for (LLSD::map_const_iterator itm = value.beginMap(); itm != value.endMap(); ++itm)
{
if (has_filter)
{
if (filter.has((*itm).first))
{
if (!filter[(*itm).first].asBoolean())
continue;
}
else if (filter.has("*"))
{
if (!filter["*"].asBoolean())
continue;
}
else
{
continue;
}
}
shallow[(*itm).first] = (*itm).second;
}
}
else if (value.isArray())
{
shallow = LLSD::emptyArray();
for (LLSD::array_const_iterator ita = value.beginArray(); ita != value.endArray(); ++ita)
{
shallow.append(*ita);
}
}
else
{
return value;
}
return shallow;
}
LLSD LL::apply_llsd_fix(size_t arity, const LLSD& args)
{
// LLSD supports a number of types, two of which are aggregates: Map and
// Array. We don't try to support Map: supporting Map would seem to
// promise that we could somehow match the string key to 'func's parameter
// names. Uh sorry, maybe in some future version of C++ with reflection.
if (args.isMap())
{
LLTHROW(LL::apply_error("LL::apply(function, Map LLSD) unsupported"));
}
// We expect an LLSD array, but what the heck, treat isUndefined() as a
// zero-length array for calling a nullary 'func'.
if (args.isUndefined() || args.isArray())
{
// this works because LLSD().size() == 0
if (args.size() != arity)
{
LLTHROW(LL::apply_error(stringize("LL::apply(function(", arity, " args), ",
args.size(), "-entry LLSD array)")));
}
return args;
}
// args is one of the scalar types
// scalar_LLSD.size() == 0, so don't test that here.
// You can pass a scalar LLSD only to a unary 'func'.
if (arity != 1)
{
LLTHROW(LL::apply_error(stringize("LL::apply(function(", arity, " args), "
"LLSD ", LLSD::typeString(args.type()), ")")));
}
// make an array of it
return llsd::array(args);
}
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