sjjaffe
/
json-validator


			
				
					
						
						
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							#pragma once

#include <algorithm>
#include <cassert>
#include <iostream>
#include <jvalidate/detail/expect.h>
#include <jvalidate/detail/number.h>
#include <string>
#include <string_view>
#include <variant>
#include <vector>

#include <jvalidate/compat/compare.h>
#include <jvalidate/forward.h>

namespace jvalidate::detail {
/**
 * @brief A helper struct for use in appending elements to a json Pointer object
 * in a way that allows it to be used as a template parameter - similar to how
 * ostream allows operator<<(void(*)(ostream&)) to pass in a function callback
 * for implementing various iomanip functions as piped (read:fluent) values.
 *
 * However, the primary usecase for this is in a template context, where I want
 * to add 0-or-more path components to a JSON-Pointer of any type, and also want
 * to support neighbor Pointers, instead of only child Pointers.
 *
 * For example, @see ValidationVisitor::visit(constraint::ConditionalConstraint)
 * where we use parent to rewind the path back to the owning scope for
 * if-then-else processing.
 */
struct parent_t {};
constexpr parent_t parent;

class Pointer {
public:
  Pointer() = default;
  Pointer(std::vector<std::variant<std::string, size_t>> const & tokens) : tokens_(tokens) {}

  /**
   * @brief Parse a JSON-Pointer from a serialized JSON-Pointer-String. In
   * principle, this should either be a factory function returning an optional/
   * throwing on error - but we'll generously assume that all JSON-Pointers are
   * valid - and therefore that an invalidly formatter pointer string will
   * point to somewhere non-existant (since it will be used in schema handling)
   */
  Pointer(std::string_view path, bool strict = false) {
    if (path.empty()) {
      return;
    }

    auto append_with_parse = [this](std::string in) {
      // Best-guess that the input token text represents a numeric value.
      // Technically - this could mean that we have an object key that is also
      // a number (e.g. the jsonized form of map<int, T>), but we can generally
      // assume that we are not going to use those kinds of paths in a reference
      // field. Therefore we don't need to include any clever tricks for storage
      if (not in.empty() && in.find_first_not_of("0123456789") == std::string::npos) {
        return tokens_.push_back(from_str<size_t>(in));
      }

      for (size_t i = 0; i < in.size(); ++i) {
        // Allow URL-Escaped characters (%\x\x) to be turned into their
        // matching ASCII characters. This allows passing abnormal chars other
        // than '/' and '~' to be handled in all contexts.
        // TODO(samjaffe): Only do this if enc is hex-like (currently throws?)
        if (in[i] == '%') {
          std::string_view enc = std::string_view(in).substr(i + 1, 2);
          in.replace(i, 3, 1, from_str<char>(enc, 16));
          continue;
        } else if (in[i] != '~') {
          // Not a special char-sequence, does not need massaging
          continue;
        }
        // In order to properly support '/' inside the property name of an
        // object, we must escape it. The designers of the JSON-Pointer RFC
        // chose to use '~' as a special signifier. Mapping '~0' to '~', and
        // '~1' to '/'.
        if (in[i + 1] == '0') {
          in.replace(i, 2, 1, '~');
        } else if (in[i + 1] == '1') {
          in.replace(i, 2, 1, '/');
        } else {
          JVALIDATE_THROW(std::runtime_error, "Illegal ~ code");
        }
      }
      tokens_.push_back(std::move(in));
    };

    // JSON-Pointers are required to start with a '/' although we only enforce
    // that rule in Reference.
    EXPECT_M(not strict || path.starts_with('/'), "JSON Pointer must start with '/'");
    path.remove_prefix(1);
    // The rules of JSON-Pointer is that if a token were to contain a '/' as a
    // strict character: then that character would be escaped, using the above
    // rules. We take advantage of string_view's sliding view to make iteration
    // easy.
    for (size_t p = path.find('/'); p != std::string::npos;
         path.remove_prefix(p + 1), p = path.find('/')) {
      append_with_parse(std::string(path.substr(0, p)));
    }

    append_with_parse(std::string(path));
  }

  /**
   * @brief Dive into a JSON object throught the entire path of the this object
   *
   * @param document A JSON Adapter document - confirming to the following spec:
   * 1. Is indexable by size_t, returning its own type
   * 2. Is indexable by std::string, returning its own type
   * 3. Indexing into a null/incorrect json type, or for an absent child is safe
   *
   * @returns A new JSON Adapter at the pointed to location, or a generic null
   * JSON object.
   */
  auto walk(Adapter auto document) const {
    for (auto const & token : tokens_) {
      document = std::visit([&document](auto const & next) { return document[next]; }, token);
    }
    return document;
  }

  /**
   * @brief Fetch the last item in this pointer as a string (for easy
   * formatting). This function is used more-or-less exclusively to support the
   * improved annotation/error listing concepts described in the article:
   * https://json-schema.org/blog/posts/fixing-json-schema-output
   */
  std::string back() const {
    struct {
      std::string operator()(std::string const & in) const { return in; }
      std::string operator()(size_t in) const { return std::to_string(in); }
    } g_as_str;
    return tokens_.empty() ? "" : std::visit(g_as_str, tokens_.back());
  }

  bool empty() const { return tokens_.empty(); }

  /**
   * @brief Determines if this JSON-Pointer is prefixed by the other
   * JSON-Pointer. For example: `"/A/B/C"_jsptr.starts_with("/A/B") == true`
   *
   * This is an important thing to know when dealing with schemas that use
   * Anchors or nest $id tags in a singular document. Consider the schema below:
   * @code{.json}
   *  {
   *    "$id": "A",
   *    "$defs": {
   *      "B": {
   *        "$anchor": "B"
   *        "$defs": {
   *          "C": {
   *            "$anchor": "C"
   *          }
   *        }
   *      }
   *    }
   *  }
   * @endcode
   *
   * How can we deduce that "A#B" and "A#C" are related to one-another as parent
   * and child nodes? First we translate them both into absolute (no-anchor)
   * forms "A#/$defs/B" and "A#/$defs/B/$defs/C". Visually - these are now
   * obviously related - but we need to expose the functionalty to make that
   * check happen (that "/$defs/B/$defs/C" starts with "/$defs/B").
   */
  bool starts_with(Pointer const & other) const {
    return other.tokens_.size() <= tokens_.size() &&
           std::equal(other.tokens_.begin(), other.tokens_.end(), tokens_.begin());
  }

  /**
   * @brief A corollary function to starts_with, create a "relative"
   * JSON-Pointer to some parent. Relative pointers are only partially supported
   * (e.g. if you tried to print it it would still emit the leading slash), so
   * the standard use case of this function is to either use it when choosing
   * a URI or Anchor that is a closer parent:
   * `Reference(uri, anchor, ptr.relative_to(other))`
   * or immediately concatenating it onto another absolute pointer:
   * `abs /= ptr.relative_to(other)`
   */
  Pointer relative_to(Pointer const & other) const {
    assert(starts_with(other));
    return Pointer(std::vector(tokens_.begin() + other.tokens_.size(), tokens_.end()));
  }

  Pointer parent(size_t i = 1) const { return Pointer({tokens_.begin(), tokens_.end() - i}); }

  Pointer & operator/=(Pointer const & relative) {
    tokens_.insert(tokens_.end(), relative.tokens_.begin(), relative.tokens_.end());
    return *this;
  }

  Pointer operator/(Pointer const & relative) const { return Pointer(*this) /= relative; }

  Pointer & operator/=(parent_t) {
    tokens_.pop_back();
    return *this;
  }

  Pointer operator/(parent_t) const { return parent(); }

  Pointer & operator/=(std::string_view key) {
    tokens_.emplace_back(std::string(key));
    return *this;
  }

  Pointer operator/(std::string_view key) const { return Pointer(*this) /= key; }

  Pointer & operator/=(size_t index) {
    tokens_.emplace_back(index);
    return *this;
  }

  Pointer operator/(size_t index) const { return Pointer(*this) /= index; }

  friend std::ostream & operator<<(std::ostream & os, Pointer const & self) {
    for (auto const & elem : self.tokens_) {
      std::visit([&os](auto const & v) { os << '/' << v; }, elem);
    }
    return os;
  }
  auto operator<=>(Pointer const &) const = default;

private:
  std::vector<std::variant<std::string, size_t>> tokens_{};
};
}