libcruft-util/json/schema.cpp

569 lines
19 KiB
C++

/*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
* Copyright 2015-2017 Danny Robson <danny@nerdcruft.net>
*/
#include "schema.hpp"
#include "tree.hpp"
#include "except.hpp"
#include "../debug.hpp"
#include "../io.hpp"
#include "../maths.hpp"
#include <regex>
///////////////////////////////////////////////////////////////////////////////
struct length_error : public json::schema_error {
length_error (const std::string &what):
schema_error (what)
{ ; }
};
//-----------------------------------------------------------------------------
struct format_error : public json::schema_error {
format_error (const std::string &what):
schema_error (what)
{ ; }
};
///////////////////////////////////////////////////////////////////////////////
static void validate (json::tree::node&, const json::tree::object&);
///////////////////////////////////////////////////////////////////////////////
static void
validate (json::tree::object &node,
const json::tree::object &schema)
{
auto properties = schema.find ("properties");
auto additional = schema.find ("additionalProperties");
auto pattern = schema.find ("patternProperties");
if (properties != schema.cend ()) {
for (const auto &kv: properties->second->as_object ()) {
auto p = node.find (kv.first);
if (p != node.cend ())
validate (*p->second, kv.second->as_object ());
else {
try {
node.insert (kv.first, (*kv.second)["default"].clone ());
validate (node[kv.first], kv.second->as_object ());
continue;
} catch (const json::key_error&)
{ ; }
if (additional != schema.cend ()) {
if (additional->second->is_boolean () && !additional->second->as_bool ())
throw json::schema_error ("additionalProperties");
validate (*p->second, additional->second->as_object ());
}
}
}
}
if (pattern != schema.cend ()) {
for (auto &cond: pattern->second->as_object ()) {
std::regex expr (cond.first, std::regex_constants::ECMAScript);
for (auto &props: node) {
if (std::regex_search (props.first, expr))
validate (*props.second, cond.second->as_object ());
}
}
}
if (schema.has ("dependencies"))
not_implemented ();
// properties must be checked after the 'properties' check has a chance to
// create the defaulted entries.
auto maxProperties = schema.find ("maxProperties");
if (maxProperties != schema.cend ())
if (node.size () > maxProperties->second->as_uint ())
throw json::schema_error ("maxProperties");
auto minProperties = schema.find ("minProperties");
if (minProperties != schema.cend ())
if (node.size () < minProperties->second->as_uint ())
throw json::schema_error ("minProperties");
auto required = schema.find ("required");
if (required != schema.cend ())
for (const auto &i: required->second->as_array ())
if (!node.has (i.as_string ()))
throw json::schema_error ("required");
}
//-----------------------------------------------------------------------------
static void
validate (json::tree::array &node,
const json::tree::object &schema)
{
// attempt to match the item and additionalItem schemas
auto items = schema.find ("items");
auto additional = schema.find ("additionalItems");
if (items != schema.cend ()) {
// items is an object, test all elements with it as a schema
if (items->second->is_object ()) {
for (auto &i: node)
validate (i, items->second->as_object ());
// items is a list of schemas, test n-elements with it as a schema
} else if (items->second->is_array ()) {
const auto &itemArray = items->second->as_array ();
size_t i = 0;
for (; i < itemArray.size () && i < node.size (); ++i)
validate (node[i], itemArray[i].as_object ());
// we've exhausted the schema list, use the additional schema
if (i == itemArray.size ()) {
if (additional->second->is_boolean ()) {
if (!additional->second->as_boolean ())
throw json::schema_error ("additional");
} else if (additional->second->is_object ()) {
for ( ; i < node.size (); ++i)
validate (node[i], additional->second->as_object ());
} else {
throw json::schema_error ("items");
}
}
}
}
auto maxItems = schema.find ("maxItems");
if (maxItems != schema.cend ())
if (node.size () > maxItems->second->as_uint ())
throw json::schema_error ("maxItems");
auto minItems = schema.find ("minItems");
if (minItems != schema.cend ())
if (node.size () < minItems->second->as_uint ())
throw json::schema_error ("minItems");
// check all element are unique
// XXX: uses a naive n^2 brute force search on equality because it's 2am
// and I don't want to write a type aware comparator for the sort.
auto unique = schema.find ("uniqueItems");
if (unique != schema.cend () && unique->second->as_boolean ())
for (size_t a = 0; a < node.size (); ++a)
for (size_t b = a + 1; b < node.size (); ++b)
if (node[a] == node[b])
throw json::schema_error ("uniqueItems");
}
//-----------------------------------------------------------------------------
static void
validate (json::tree::string &node,
const json::tree::object &schema)
{
const auto &val = node.native ();
// check length is less than a maximum
auto maxLength = schema.find ("maxLength");
if (maxLength != schema.cend ()) {
auto cmp = maxLength->second->as_number ().uint ();
if (!util::is_integer (cmp))
throw length_error ("maxLength");
if (val.size () > cmp)
throw length_error ("maxLength");
}
// check length is greater than a maximum
auto minLength = schema.find ("minLength");
if (minLength != schema.cend ()) {
auto cmp = minLength->second->as_number ().uint ();
if (!util::is_integer (cmp))
throw length_error ("minLength");
if (val.size () < cmp)
throw length_error ("minLength");
}
// check the string conforms to a regex
// Note: this uses the c++11 regex engine which slightly differs from ECMA 262
auto pattern = schema.find ("pattern");
if (pattern != schema.cend ()) {
std::regex r (pattern->second->as_string ().native (),
std::regex_constants::ECMAScript);
if (!std::regex_search (val, r))
throw format_error ("pattern");
}
}
//-----------------------------------------------------------------------------
template <typename T>
static void
validate_number (T val, const json::tree::object &schema) {
using R = json::tree::number::repr_t;
// check strictly positive integer multiple
auto mult = schema.find ("multipleOf");
if (mult != schema.cend ()) {
const auto &div = mult->second->as_number ();
switch (div.repr ()) {
case R::REAL: if (util::exactly_zero (std::fmod (val, div.real ()))) throw json::schema_error ("multipleOf"); break;
case R::SINT: if (util::exactly_zero (std::fmod (val, div.sint ()))) throw json::schema_error ("multipleOf"); break;
case R::UINT: if (util::exactly_zero (std::fmod (val, div.uint ()))) throw json::schema_error ("multipleOf"); break;
}
}
// check maximum holds. exclusive requires max condition.
auto max = schema.find ("maximum");
auto exclusiveMax = schema.find ("exclusiveMaximum");
if (max != schema.end ()) {
const auto &cmp = max->second->as_number ();
if (exclusiveMax != schema.end () && exclusiveMax->second->as_boolean ()) {
switch (cmp.repr ()) {
case R::REAL:
if (T(val) >= cmp.real ())
throw json::schema_error ("exclusiveMax");
break;
case R::SINT:
if (json::tree::number::sint_t(std::numeric_limits<T>::max ()) >= cmp.sint () &&
val >= T(cmp.sint ()))
{
throw json::schema_error ("exclusiveMax");
}
break;
case R::UINT:
if (json::tree::number::uint_t(std::numeric_limits<T>::max ()) >= cmp.uint () &&
val >= T(cmp.uint ()))
{
throw json::schema_error ("exclusiveMax");
}
break;
}
} else {
switch (cmp.repr ()) {
case R::REAL:
if (T(val) > cmp.real ())
throw json::schema_error ("maximum");
break;
case R::SINT:
if (json::tree::number::sint_t(std::numeric_limits<T>::max ()) >= cmp.sint () &&
val >= T(cmp.sint ()))
{
throw json::schema_error ("maximum");
}
break;
case R::UINT:
if (json::tree::number::uint_t(std::numeric_limits<T>::max ()) >= cmp.uint () &&
val >= T(cmp.uint ()))
{
throw json::schema_error ("maximum");
}
break;
}
}
} else {
if (exclusiveMax != schema.cend ())
throw json::schema_error ("exclusiveMax");
}
// check minimum holds. exclusive requires min condition
auto min = schema.find ("minimum");
auto exclusiveMin = schema.find ("exclusiveMinimum");
if (min != schema.end ()) {
const auto &cmp = min->second->as_number ();
if (exclusiveMin != schema.end () && exclusiveMin->second->as_boolean ()) {
switch (cmp.repr ()) {
case R::REAL:
if (T(val) < cmp.real ())
throw json::schema_error ("exclusiveMin");
break;
case R::SINT:
if (cmp.sint () > json::tree::number::sint_t(std::numeric_limits<T>::min ()) &&
val < T(cmp.sint ()))
{
throw json::schema_error ("exclusiveMin");
}
break;
case R::UINT:
if (cmp.uint () > json::tree::number::uint_t(std::numeric_limits<T>::min ()) &&
val < T(cmp.uint ()))
{
throw json::schema_error ("exclusiveMin");
}
break;
}
} else {
switch (cmp.repr ()) {
case R::REAL:
if (T(val) <= cmp.real ())
throw json::schema_error ("minimum");
break;
case R::SINT:
if (cmp.sint () >= json::tree::number::sint_t(std::numeric_limits<T>::min ()) &&
val <= T(cmp.sint ()))
{
throw json::schema_error ("minimum");
}
break;
case R::UINT:
if (cmp.uint () >= json::tree::number::uint_t(std::numeric_limits<T>::min ()) &&
val <= T(cmp.uint ()))
{
throw json::schema_error ("minimum");
}
break;
}
}
} else {
if (exclusiveMin != schema.cend ())
throw json::schema_error ("exclusiveMin");
}
}
//-----------------------------------------------------------------------------
static void
validate (json::tree::number &node,
const json::tree::object &schema)
{
using N = json::tree::number;
using R = N::repr_t;
switch (node.repr ()) {
case R::REAL: validate_number<N::real_t> (node.real (), schema); break;
case R::SINT: validate_number<N::sint_t> (node.sint (), schema); break;
case R::UINT: validate_number<N::uint_t> (node.uint (), schema); break;
}
}
//-----------------------------------------------------------------------------
static void
validate (json::tree::boolean&,
const json::tree::object&)
{ ; }
//-----------------------------------------------------------------------------
static void
validate (json::tree::null&,
const json::tree::object&)
{ ; }
//-----------------------------------------------------------------------------
static std::string
to_string (json::tree::type_t t)
{
switch (t) {
case json::tree::OBJECT: return "object";
case json::tree::ARRAY: return "array";
case json::tree::STRING: return "string";
case json::tree::NUMBER: return "number";
case json::tree::BOOLEAN: return "boolean";
case json::tree::NONE: return "null";
}
unreachable ();
}
//-----------------------------------------------------------------------------
static bool
is_type_valid (const json::tree::node &node, const std::string &type)
{
if (type == "integer") return node.is_integer ();
if (type == "number") return node.is_number ();
if (type == "string") return node.is_string ();
if (type == "object") return node.is_object ();
if (type == "array") return node.is_array ();
if (type == "boolean") return node.is_boolean ();
if (type == "null") return node.is_null ();
return false;
}
//-----------------------------------------------------------------------------
static void
validate (json::tree::node &node,
const json::tree::object &schema)
{
// check the value is in the prescribed list
auto enumPos = schema.find ("enum");
if (enumPos != schema.cend ()) {
auto pos = std::find (enumPos->second->as_array ().cbegin (),
enumPos->second->as_array ().cend (),
node);
if (pos == enumPos->second->as_array ().cend ())
throw json::schema_error ("enum");
}
// check the value is the correct type
auto type = schema.find ("type");
if (type != schema.cend ()) {
// check against a single named type
if (type->second->is_string ()) {
if (!is_type_valid (node, type->second->as_string ()))
throw json::schema_error ("type");
// check against an array of types
} else if (type->second->is_array ()) {
auto pos = std::find_if (type->second->as_array ().begin (),
type->second->as_array ().end (),
[&] (const auto &i) { return i.as_string () == to_string (node.type ()); });
if (pos == type->second->as_array ().end ())
throw json::schema_error ("type");
} else
throw json::schema_error ("type");
}
auto allOf = schema.find ("allOf");
if (allOf != schema.cend ()) {
for (const auto &i: allOf->second->as_array ())
validate (node, i.as_object ());
}
auto anyOf = schema.find ("anyOf");
if (anyOf != schema.cend ()) {
bool success = false;
for (const auto &i: anyOf->second->as_array ()) {
try {
validate (node, i.as_object ());
success = true;
break;
} catch (const json::schema_error&)
{ continue; }
}
if (!success)
throw json::schema_error ("anyOf");
}
auto oneOf = schema.find ("oneOf");
if (oneOf != schema.cend ()) {
unsigned count = 0;
for (const auto &i: oneOf->second->as_array ()) {
try {
validate (node, i.as_object ());
count++;
} catch (const json::schema_error&)
{ ; }
if (count > 1)
throw json::schema_error ("oneOf");
}
if (count != 1)
throw json::schema_error ("oneOf");
}
auto notSchema = schema.find ("not");
if (notSchema != schema.cend ()) {
for (const auto &i: notSchema->second->as_array ()) {
bool valid = false;
try {
validate (node, i.as_object ());
valid = true;
} catch (const json::schema_error&)
{ ; }
if (valid)
throw json::schema_error ("not");
}
}
switch (node.type ()) {
case json::tree::OBJECT: validate (node.as_object (), schema); return;
case json::tree::ARRAY: validate (node.as_array (), schema); return;
case json::tree::STRING: validate (node.as_string (), schema); return;
case json::tree::NUMBER: validate (node.as_number (), schema); return;
case json::tree::BOOLEAN: validate (node.as_boolean (), schema); return;
case json::tree::NONE: validate (node.as_null (), schema); return;
}
unreachable ();
}
//-----------------------------------------------------------------------------
void
json::schema::validate (json::tree::node &data,
const json::tree::object &schema)
{
auto title = schema.find ("title");
if (title != schema.cend ())
if (!title->second->is_string ())
throw json::schema_error ("title");
auto description = schema.find ("description");
if (description != schema.cend ())
if (!description->second->is_string ())
throw json::schema_error ("description");
return ::validate (data, schema.as_object ());
}
//-----------------------------------------------------------------------------
void
json::schema::validate (json::tree::node &data,
const std::experimental::filesystem::path &schema_path)
{
const util::mapped_file schema_data (schema_path);
auto schema_object = json::tree::parse (util::view(schema_data).cast<const char*> ());
validate (data, schema_object->as_object ());
}
///////////////////////////////////////////////////////////////////////////////
#include "schema/except.hpp"
#include "schema/base.hpp"
#include "../io.hpp"
#include "../view.hpp"
#include <map>
json::schema::validator::validator(std::experimental::filesystem::path const &path):
validator (*json::tree::parse (path))
{ ; }
json::schema::validator::validator (json::tree::node const &definition):
m_base (definition)
{ ; }
bool
json::schema::validator::validate (json::tree::node &data) const
{
std::vector<util::json::schema::constraint::failure> res;
m_base.validate (std::back_inserter(res), data);
return res.empty ();
}