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-rw-r--r--indra/llcommon/llsdutil.cpp364
1 files changed, 364 insertions, 0 deletions
diff --git a/indra/llcommon/llsdutil.cpp b/indra/llcommon/llsdutil.cpp
index aa0e0f3696..c8d8030e87 100644
--- a/indra/llcommon/llsdutil.cpp
+++ b/indra/llcommon/llsdutil.cpp
@@ -46,6 +46,11 @@
#endif
#include "llsdserialize.h"
+#include "stringize.h"
+
+#include <map>
+#include <set>
+#include <boost/range.hpp>
// U32
LLSD ll_sd_from_U32(const U32 val)
@@ -171,6 +176,15 @@ char* ll_print_sd(const LLSD& sd)
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 = 10 * 1024;
@@ -304,3 +318,353 @@ BOOL compare_llsd_with_template(
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()
+ {
+ 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
+ {
+ 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
+{
+ // 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)
+{
+ // 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)
+{
+ // 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;
+
+#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);
+ // The usual caveats about comparing floating-point numbers apply. This is
+ // only useful when we expect identical bit representation for a given
+ // Real value, e.g. for integer-valued Reals.
+ COMPARE_SCALAR(Real);
+ 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))
+ 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]))
+ 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 << "): "
+ "unknown type " << lhs.type() << LL_ENDL;
+ return false; // pacify the compiler
+ }
+}