/// \file amf.cpp
/// Holds all code for the AMF namespace.
#include "amf.h"
#include "defines.h"
#include <sstream>
/// Returns the std::string Indice for the current object, if available.
/// Returns an empty string if no indice exists.
std::string AMF::Object::Indice(){
return myIndice;
}
/// Returns the AMF::obj0type AMF0 object type for this object.
AMF::obj0type AMF::Object::GetType(){
return myType;
}
/// Returns the numeric value of this object, if available.
/// If this object holds no numeric value, 0 is returned.
double AMF::Object::NumValue(){
return numval;
}
/// Returns the std::string value of this object, if available.
/// If this object holds no string value, an empty string is returned.
std::string AMF::Object::StrValue(){
return strval;
}
/// Returns the C-string value of this object, if available.
/// If this object holds no string value, an empty C-string is returned.
const char *AMF::Object::Str(){
return strval.c_str();
}
/// Returns a count of the amount of objects this object currently holds.
/// If this object is not a container type, this function will always return 0.
int AMF::Object::hasContent(){
return contents.size();
}
/// Adds an AMF::Object to this object. Works for all types, but only makes sense for container
/// types.
void AMF::Object::addContent(AMF::Object c){
contents.push_back(c);
}
/// Returns a pointer to the object held at indice i.
/// Returns AMF::AMF0_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param i The indice of the object in this container.
AMF::Object *AMF::Object::getContentP(unsigned int i){
if (i >= contents.size()){return 0;}
return &contents.at(i);
}
/// Returns a copy of the object held at indice i.
/// Returns a AMF::AMF0_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param i The indice of the object in this container.
AMF::Object AMF::Object::getContent(unsigned int i){
return contents.at(i);
}
/// Returns a pointer to the object held at indice s.
/// Returns NULL if no object is held at this indice.
/// \param s The indice of the object in this container.
AMF::Object *AMF::Object::getContentP(std::string s){
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
if (it->Indice() == s){return &(*it);}
}
return 0;
}
/// Returns a copy of the object held at indice s.
/// Returns a AMF::AMF0_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param s The indice of the object in this container.
AMF::Object AMF::Object::getContent(std::string s){
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
if (it->Indice() == s){return *it;}
}
return AMF::Object("error", AMF0_DDV_CONTAINER);
}
/// Default constructor.
/// Simply fills the data with AMF::Object("error", AMF0_DDV_CONTAINER)
AMF::Object::Object(){
*this = AMF::Object("error", AMF0_DDV_CONTAINER);
}// default constructor
/// Constructor for numeric objects.
/// The object type is by default AMF::AMF0_NUMBER, but this can be forced to a different value.
/// \param indice The string indice of this object in its container, or empty string if none.
/// Numeric indices are automatic. \param val The numeric value of this object. Numeric AMF0 objects
/// only support double-type values. \param setType The object type to force this object to.
AMF::Object::Object(std::string indice, double val, AMF::obj0type setType){// num type initializer
myIndice = indice;
myType = setType;
strval = "";
numval = val;
}
/// Constructor for string objects.
/// The object type is by default AMF::AMF0_STRING, but this can be forced to a different value.
/// There is no need to manually change the type to AMF::AMF0_LONGSTRING, this will be done
/// automatically. \param indice The string indice of this object in its container, or empty string
/// if none. Numeric indices are automatic. \param val The string value of this object. \param
/// setType The object type to force this object to.
AMF::Object::Object(std::string indice, std::string val,
AMF::obj0type setType){// str type initializer
myIndice = indice;
myType = setType;
strval = val;
numval = 0;
}
/// Constructor for string objects.
/// The object type is by default AMF::AMF0_STRING, but this can be forced to a different value.
/// There is no need to manually change the type to AMF::AMF0_LONGSTRING, this will be done
/// automatically. \param indice The string indice of this object in its container, or empty string
/// if none. Numeric indices are automatic. \param val The string value of this object. \param
/// setType The object type to force this object to.
AMF::Object::Object(std::string indice, const char *val,
AMF::obj0type setType){// str type initializer
myIndice = indice;
myType = setType;
strval = val;
numval = 0;
}
/// Constructor for container objects.
/// The object type is by default AMF::AMF0_OBJECT, but this can be forced to a different value.
/// \param indice The string indice of this object in its container, or empty string if none.
/// Numeric indices are automatic. \param setType The object type to force this object to.
AMF::Object::Object(std::string indice, AMF::obj0type setType){// object type initializer
myIndice = indice;
myType = setType;
strval = "";
numval = 0;
}
/// Return the contents as a human-readable string.
/// If this object contains other objects, it will call itself recursively
/// and print all nested content as well.
std::string AMF::Object::Print(std::string indent){
std::stringstream st;
st << indent;
// print my type
switch (myType){
case AMF::AMF0_NUMBER: st << "Number"; break;
case AMF::AMF0_BOOL: st << "Bool"; break;
case AMF::AMF0_STRING: // short string
case AMF::AMF0_LONGSTRING: st << "String"; break;
case AMF::AMF0_OBJECT: st << "Object"; break;
case AMF::AMF0_MOVIECLIP: st << "MovieClip"; break;
case AMF::AMF0_NULL: st << "Null"; break;
case AMF::AMF0_UNDEFINED: st << "Undefined"; break;
case AMF::AMF0_REFERENCE: st << "Reference"; break;
case AMF::AMF0_ECMA_ARRAY: st << "ECMA Array"; break;
case AMF::AMF0_OBJ_END: st << "Object end"; break;
case AMF::AMF0_STRICT_ARRAY: st << "Strict Array"; break;
case AMF::AMF0_DATE: st << "Date"; break;
case AMF::AMF0_UNSUPPORTED: st << "Unsupported"; break;
case AMF::AMF0_RECORDSET: st << "Recordset"; break;
case AMF::AMF0_XMLDOC: st << "XML Document"; break;
case AMF::AMF0_TYPED_OBJ: st << "Typed Object"; break;
case AMF::AMF0_UPGRADE: st << "Upgrade to AMF3"; break;
case AMF::AMF0_DDV_CONTAINER: st << "DDVTech Container"; break;
}
// print my string indice, if available
st << " " << myIndice << " ";
// print my numeric or string contents
switch (myType){
case AMF::AMF0_NUMBER:
case AMF::AMF0_BOOL:
case AMF::AMF0_REFERENCE:
case AMF::AMF0_DATE: st << numval; break;
case AMF::AMF0_STRING:
case AMF::AMF0_LONGSTRING:
case AMF::AMF0_XMLDOC:
case AMF::AMF0_TYPED_OBJ: st << strval; break;
default: break; // we don't care about the rest, and don't want a compiler warning...
}
st << std::endl;
// if I hold other objects, print those too, recursively.
if (contents.size() > 0){
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
st << it->Print(indent + " ");
}
}
return st.str();
}// print
/// Packs the AMF object to a std::string for transfer over the network.
/// If the object is a container type, this function will call itself recursively and contain all
/// contents. Tip: When sending multiple AMF objects in one go, put them in a single
/// AMF::AMF0_DDV_CONTAINER for easy transfer.
std::string AMF::Object::Pack(){
std::string r = "";
// check for string/longstring conversion
if ((myType == AMF::AMF0_STRING) && (strval.size() > 0xFFFF)){myType = AMF::AMF0_LONGSTRING;}
// skip output of DDV container types, they do not exist. Only output their contents.
if (myType != AMF::AMF0_DDV_CONTAINER){r += myType;}
// output the properly formatted AMF0 data stream for this object's contents.
switch (myType){
case AMF::AMF0_NUMBER:
r += *(((char *)&numval) + 7);
r += *(((char *)&numval) + 6);
r += *(((char *)&numval) + 5);
r += *(((char *)&numval) + 4);
r += *(((char *)&numval) + 3);
r += *(((char *)&numval) + 2);
r += *(((char *)&numval) + 1);
r += *(((char *)&numval));
break;
case AMF::AMF0_DATE:
r += *(((char *)&numval) + 7);
r += *(((char *)&numval) + 6);
r += *(((char *)&numval) + 5);
r += *(((char *)&numval) + 4);
r += *(((char *)&numval) + 3);
r += *(((char *)&numval) + 2);
r += *(((char *)&numval) + 1);
r += *(((char *)&numval));
r += (char)0; // timezone always 0
r += (char)0; // timezone always 0
break;
case AMF::AMF0_BOOL: r += (char)numval; break;
case AMF::AMF0_STRING:
r += strval.size() / 256;
r += strval.size() % 256;
r += strval;
break;
case AMF::AMF0_LONGSTRING:
case AMF::AMF0_XMLDOC: // is always a longstring
r += strval.size() / (256 * 256 * 256);
r += strval.size() / (256 * 256);
r += strval.size() / 256;
r += strval.size() % 256;
r += strval;
break;
case AMF::AMF0_TYPED_OBJ: // is an object, with the classname first
r += Indice().size() / 256;
r += Indice().size() % 256;
r += Indice();
/* no break */
case AMF::AMF0_OBJECT:
if (contents.size() > 0){
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
r += it->Indice().size() / 256;
r += it->Indice().size() % 256;
r += it->Indice();
r += it->Pack();
}
}
r += (char)0;
r += (char)0;
r += (char)9;
break;
case AMF::AMF0_MOVIECLIP:
case AMF::AMF0_OBJ_END:
case AMF::AMF0_UPGRADE:
case AMF::AMF0_NULL:
case AMF::AMF0_UNDEFINED:
case AMF::AMF0_RECORDSET:
case AMF::AMF0_UNSUPPORTED:
// no data to add
break;
case AMF::AMF0_REFERENCE:
r += (char)((int)numval / 256);
r += (char)((int)numval % 256);
break;
case AMF::AMF0_ECMA_ARRAY:{
int arrlen = 0;
if (contents.size() > 0){
arrlen = contents.size();
r += arrlen / (256 * 256 * 256);
r += arrlen / (256 * 256);
r += arrlen / 256;
r += arrlen % 256;
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
r += it->Indice().size() / 256;
r += it->Indice().size() % 256;
r += it->Indice();
r += it->Pack();
}
}else{
r += (char)0;
r += (char)0;
r += (char)0;
r += (char)0;
}
r += (char)0;
r += (char)0;
r += (char)9;
}break;
case AMF::AMF0_STRICT_ARRAY:{
int arrlen = 0;
if (contents.size() > 0){
arrlen = contents.size();
r += arrlen / (256 * 256 * 256);
r += arrlen / (256 * 256);
r += arrlen / 256;
r += arrlen % 256;
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
r += it->Pack();
}
}else{
r += (char)0;
r += (char)0;
r += (char)0;
r += (char)0;
}
}break;
case AMF::AMF0_DDV_CONTAINER: // only send contents
if (contents.size() > 0){
for (std::vector<AMF::Object>::iterator it = contents.begin(); it != contents.end(); it++){
r += it->Pack();
}
}
break;
}
return r;
}// pack
/// Parses a single AMF0 type - used recursively by the AMF::parse() functions.
/// This function updates i every call with the new position in the data.
/// \param data The raw data to parse.
/// \param len The size of the raw data.
/// \param i Current parsing position in the raw data.
/// \param name Indice name for any new object created.
/// \returns A single AMF::Object, parsed from the raw data.
AMF::Object AMF::parseOne(const unsigned char *&data, unsigned int &len, unsigned int &i,
std::string name){
std::string tmpstr;
unsigned int tmpi = 0;
unsigned char tmpdbl[8];
double *d; // hack to work around strict aliasing
switch (data[i]){
case AMF::AMF0_NUMBER:
tmpdbl[7] = data[i + 1];
tmpdbl[6] = data[i + 2];
tmpdbl[5] = data[i + 3];
tmpdbl[4] = data[i + 4];
tmpdbl[3] = data[i + 5];
tmpdbl[2] = data[i + 6];
tmpdbl[1] = data[i + 7];
tmpdbl[0] = data[i + 8];
i += 9; // skip 8(a double)+1 forwards
d = (double *)tmpdbl;
return AMF::Object(name, *d, AMF::AMF0_NUMBER);
break;
case AMF::AMF0_DATE:
tmpdbl[7] = data[i + 1];
tmpdbl[6] = data[i + 2];
tmpdbl[5] = data[i + 3];
tmpdbl[4] = data[i + 4];
tmpdbl[3] = data[i + 5];
tmpdbl[2] = data[i + 6];
tmpdbl[1] = data[i + 7];
tmpdbl[0] = data[i + 8];
i += 11; // skip 8(a double)+1+timezone(2) forwards
d = (double *)tmpdbl;
return AMF::Object(name, *d, AMF::AMF0_DATE);
break;
case AMF::AMF0_BOOL:
i += 2; // skip bool+1 forwards
if (data[i - 1] == 0){
return AMF::Object(name, (double)0, AMF::AMF0_BOOL);
}else{
return AMF::Object(name, (double)1, AMF::AMF0_BOOL);
}
break;
case AMF::AMF0_REFERENCE:
tmpi = data[i + 1] * 256 + data[i + 2]; // get the ref number value as a double
i += 3; // skip ref+1 forwards
return AMF::Object(name, (double)tmpi, AMF::AMF0_REFERENCE);
break;
case AMF::AMF0_XMLDOC:
tmpi = data[i + 1] * 256 * 256 * 256 + data[i + 2] * 256 * 256 + data[i + 3] * 256 +
data[i + 4]; // set tmpi to UTF-8-long length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 5, (size_t)tmpi); // add the string data
i += tmpi + 5; // skip length+size+1 forwards
return AMF::Object(name, tmpstr, AMF::AMF0_XMLDOC);
break;
case AMF::AMF0_LONGSTRING:
tmpi = data[i + 1] * 256 * 256 * 256 + data[i + 2] * 256 * 256 + data[i + 3] * 256 +
data[i + 4]; // set tmpi to UTF-8-long length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 5, (size_t)tmpi); // add the string data
i += tmpi + 5; // skip length+size+1 forwards
return AMF::Object(name, tmpstr, AMF::AMF0_LONGSTRING);
break;
case AMF::AMF0_STRING:
tmpi = data[i + 1] * 256 + data[i + 2]; // set tmpi to UTF-8 length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 3, (size_t)tmpi); // add the string data
i += tmpi + 3; // skip length+size+1 forwards
return AMF::Object(name, tmpstr, AMF::AMF0_STRING);
break;
case AMF::AMF0_NULL:
case AMF::AMF0_UNDEFINED:
case AMF::AMF0_UNSUPPORTED:
++i;
return AMF::Object(name, (double)0, (AMF::obj0type)data[i - 1]);
break;
case AMF::AMF0_OBJECT:{
++i;
AMF::Object ret(name, AMF::AMF0_OBJECT);
while (data[i] + data[i + 1] != 0){// while not encountering 0x0000 (we assume 0x000009)
tmpi = data[i] * 256 + data[i + 1]; // set tmpi to the UTF-8 length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 2, (size_t)tmpi); // add the string data
i += tmpi + 2; // skip length+size forwards
ret.addContent(AMF::parseOne(
data, len, i,
tmpstr)); // add content, recursively parsed, updating i, setting indice to tmpstr
}
i += 3; // skip 0x000009
return ret;
}break;
case AMF::AMF0_TYPED_OBJ:{
++i;
tmpi = data[i] * 256 + data[i + 1]; // set tmpi to the UTF-8 length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 2, (size_t)tmpi); // add the string data
AMF::Object ret(tmpstr, AMF::AMF0_TYPED_OBJ); // the object is not named "name" but tmpstr
while (data[i] + data[i + 1] != 0){// while not encountering 0x0000 (we assume 0x000009)
tmpi = data[i] * 256 + data[i + 1]; // set tmpi to the UTF-8 length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 2, (size_t)tmpi); // add the string data
i += tmpi + 2; // skip length+size forwards
ret.addContent(AMF::parseOne(
data, len, i,
tmpstr)); // add content, recursively parsed, updating i, setting indice to tmpstr
}
i += 3; // skip 0x000009
return ret;
}break;
case AMF::AMF0_ECMA_ARRAY:{
++i;
AMF::Object ret(name, AMF::AMF0_ECMA_ARRAY);
i += 4; // ignore the array length, we re-calculate it
while (data[i] + data[i + 1] != 0){// while not encountering 0x0000 (we assume 0x000009)
tmpi = data[i] * 256 + data[i + 1]; // set tmpi to the UTF-8 length
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i + 2, (size_t)tmpi); // add the string data
i += tmpi + 2; // skip length+size forwards
ret.addContent(AMF::parseOne(
data, len, i,
tmpstr)); // add content, recursively parsed, updating i, setting indice to tmpstr
}
i += 3; // skip 0x000009
return ret;
}break;
case AMF::AMF0_STRICT_ARRAY:{
AMF::Object ret(name, AMF::AMF0_STRICT_ARRAY);
tmpi = data[i + 1] * 256 * 256 * 256 + data[i + 2] * 256 * 256 + data[i + 3] * 256 +
data[i + 4]; // set tmpi to array length
i += 5; // skip size+1 forwards
while (tmpi > 0){// while not done parsing array
ret.addContent(
AMF::parseOne(data, len, i, "arrVal")); // add content, recursively parsed, updating i
--tmpi;
}
return ret;
}break;
}
ERROR_MSG("Error: Unimplemented AMF type %hhx - returning.", data[i]);
return AMF::Object("error", AMF::AMF0_DDV_CONTAINER);
}// parseOne
/// Parses a C-string to a valid AMF::Object.
/// This function will find all AMF objects in the string and return
/// them all packed in a single AMF::AMF0_DDV_CONTAINER AMF::Object.
AMF::Object AMF::parse(const unsigned char *data, unsigned int len){
AMF::Object ret("returned", AMF::AMF0_DDV_CONTAINER); // container type
unsigned int i = 0, j = 0;
while (i < len){
ret.addContent(AMF::parseOne(data, len, i, ""));
if (i > j){
j = i;
}else{
return ret;
}
}
return ret;
}// parse
/// Parses a std::string to a valid AMF::Object.
/// This function will find all AMF objects in the string and return
/// them all packed in a single AMF::AMF0_DDV_CONTAINER AMF::Object.
AMF::Object AMF::parse(std::string data){
return AMF::parse((const unsigned char *)data.c_str(), data.size());
}// parse
/// Returns the std::string Indice for the current object, if available.
/// Returns an empty string if no indice exists.
std::string AMF::Object3::Indice(){
return myIndice;
}
/// Returns the AMF::obj0type AMF0 object type for this object.
AMF::obj3type AMF::Object3::GetType(){
return myType;
}
/// Returns the double value of this object, if available.
/// If this object holds no double value, 0 is returned.
double AMF::Object3::DblValue(){
return dblval;
}
/// Returns the integer value of this object, if available.
/// If this object holds no integer value, 0 is returned.
int AMF::Object3::IntValue(){
return intval;
}
/// Returns the std::string value of this object, if available.
/// If this object holds no string value, an empty string is returned.
std::string AMF::Object3::StrValue(){
return strval;
}
/// Returns the C-string value of this object, if available.
/// If this object holds no string value, an empty C-string is returned.
const char *AMF::Object3::Str(){
return strval.c_str();
}
/// Returns a count of the amount of objects this object currently holds.
/// If this object is not a container type, this function will always return 0.
int AMF::Object3::hasContent(){
return contents.size();
}
/// Adds an AMF::Object to this object. Works for all types, but only makes sense for container
/// types.
void AMF::Object3::addContent(AMF::Object3 c){
contents.push_back(c);
}
/// Returns a pointer to the object held at indice i.
/// Returns AMF::AMF3_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param i The indice of the object in this container.
AMF::Object3 *AMF::Object3::getContentP(int i){
return &contents.at(i);
}
/// Returns a copy of the object held at indice i.
/// Returns a AMF::AMF3_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param i The indice of the object in this container.
AMF::Object3 AMF::Object3::getContent(int i){
return contents.at(i);
}
/// Returns a pointer to the object held at indice s.
/// Returns NULL if no object is held at this indice.
/// \param s The indice of the object in this container.
AMF::Object3 *AMF::Object3::getContentP(std::string s){
for (std::vector<AMF::Object3>::iterator it = contents.begin(); it != contents.end(); it++){
if (it->Indice() == s){return &(*it);}
}
return 0;
}
/// Returns a copy of the object held at indice s.
/// Returns a AMF::AMF0_DDV_CONTAINER of indice "error" if no object is held at this indice.
/// \param s The indice of the object in this container.
AMF::Object3 AMF::Object3::getContent(std::string s){
for (std::vector<AMF::Object3>::iterator it = contents.begin(); it != contents.end(); it++){
if (it->Indice() == s){return *it;}
}
return AMF::Object3("error", AMF3_DDV_CONTAINER);
}
/// Default constructor.
/// Simply fills the data with AMF::Object3("error", AMF3_DDV_CONTAINER)
AMF::Object3::Object3(){
*this = AMF::Object3("error", AMF3_DDV_CONTAINER);
}// default constructor
/// Constructor for double objects.
/// The object type is by default AMF::AMF3_DOUBLE, but this can be forced to a different value.
/// \param indice The string indice of this object in its container, or empty string if none.
/// Numeric indices are automatic. \param val The numeric value of this object. Double AMF3 objects
/// only support double-type values. \param setType The object type to force this object to.
AMF::Object3::Object3(std::string indice, double val,
AMF::obj3type setType){// num type initializer
myIndice = indice;
myType = setType;
strval = "";
dblval = val;
intval = 0;
}
/// Constructor for integer objects.
/// The object type is by default AMF::AMF3_INTEGER, but this can be forced to a different value.
/// \param indice The string indice of this object in its container, or empty string if none.
/// Numeric indices are automatic. \param val The numeric value of this object. Integer AMF3 objects
/// only support integer-type values. \param setType The object type to force this object to.
AMF::Object3::Object3(std::string indice, int val, AMF::obj3type setType){// num type initializer
myIndice = indice;
myType = setType;
strval = "";
dblval = val;
intval = 0;
}
/// Constructor for string objects.
/// The object type is by default AMF::AMF0_STRING, but this can be forced to a different value.
/// There is no need to manually change the type to AMF::AMF0_LONGSTRING, this will be done
/// automatically. \param indice The string indice of this object in its container, or empty string
/// if none. Numeric indices are automatic. \param val The string value of this object. \param
/// setType The object type to force this object to.
AMF::Object3::Object3(std::string indice, std::string val,
AMF::obj3type setType){// str type initializer
myIndice = indice;
myType = setType;
strval = val;
dblval = 0;
intval = 0;
}
/// Constructor for container objects.
/// The object type is by default AMF::AMF0_OBJECT, but this can be forced to a different value.
/// \param indice The string indice of this object in its container, or empty string if none.
/// Numeric indices are automatic. \param setType The object type to force this object to.
AMF::Object3::Object3(std::string indice, AMF::obj3type setType){// object type initializer
myIndice = indice;
myType = setType;
strval = "";
dblval = 0;
intval = 0;
}
/// Return the contents as a human-readable string.
/// If this object contains other objects, it will call itself recursively
/// and print all nested content as well.
std::string AMF::Object3::Print(std::string indent){
std::stringstream st;
st << indent;
// print my type
switch (myType){
case AMF::AMF3_UNDEFINED: st << "Undefined"; break;
case AMF::AMF3_NULL: st << "Null"; break;
case AMF::AMF3_FALSE: st << "False"; break;
case AMF::AMF3_TRUE: st << "True"; break;
case AMF::AMF3_INTEGER: st << "Integer"; break;
case AMF::AMF3_DOUBLE: st << "Double"; break;
case AMF::AMF3_STRING: st << "String"; break;
case AMF::AMF3_XMLDOC: st << "XML Doc"; break;
case AMF::AMF3_DATE: st << "Date"; break;
case AMF::AMF3_ARRAY: st << "Array"; break;
case AMF::AMF3_OBJECT: st << "Object"; break;
case AMF::AMF3_XML: st << "XML"; break;
case AMF::AMF3_BYTES: st << "ByteArray"; break;
case AMF::AMF3_DDV_CONTAINER: st << "DDVTech Container"; break;
}
// print my string indice, if available
st << " " << myIndice << " ";
// print my numeric or string contents
switch (myType){
case AMF::AMF3_INTEGER: st << intval; break;
case AMF::AMF3_DOUBLE: st << dblval; break;
case AMF::AMF3_STRING:
case AMF::AMF3_XMLDOC:
case AMF::AMF3_XML:
case AMF::AMF3_BYTES:
if (intval > 0){
st << "REF" << intval;
}else{
st << strval;
}
break;
case AMF::AMF3_DATE:
if (intval > 0){
st << "REF" << intval;
}else{
st << dblval;
}
break;
case AMF::AMF3_ARRAY:
case AMF::AMF3_OBJECT:
if (intval > 0){st << "REF" << intval;}
break;
default: break; // we don't care about the rest, and don't want a compiler warning...
}
st << std::endl;
// if I hold other objects, print those too, recursively.
if (contents.size() > 0){
for (std::vector<AMF::Object3>::iterator it = contents.begin(); it != contents.end(); it++){
st << it->Print(indent + " ");
}
}
return st.str();
}// print
/// Packs the AMF object to a std::string for transfer over the network.
/// If the object is a container type, this function will call itself recursively and contain all
/// contents. Tip: When sending multiple AMF objects in one go, put them in a single
/// AMF::AMF0_DDV_CONTAINER for easy transfer.
std::string AMF::Object3::Pack(){
std::string r = "";
return r;
}// pack
/// Parses a single AMF3 type - used recursively by the AMF::parse3() functions.
/// This function updates i every call with the new position in the data.
/// \param data The raw data to parse.
/// \param len The size of the raw data.
/// \param i Current parsing position in the raw data.
/// \param name Indice name for any new object created.
/// \returns A single AMF::Object3, parsed from the raw data.
AMF::Object3 AMF::parseOne3(const unsigned char *&data, unsigned int &len, unsigned int &i,
std::string name){
std::string tmpstr;
unsigned int tmpi = 0;
unsigned int arrsize = 0;
unsigned char tmpdbl[8];
double *d; // hack to work around strict aliasing
switch (data[i]){
case AMF::AMF3_UNDEFINED:
case AMF::AMF3_NULL:
case AMF::AMF3_FALSE:
case AMF::AMF3_TRUE:
++i;
return AMF::Object3(name, (AMF::obj3type)data[i - 1]);
break;
case AMF::AMF3_INTEGER:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
return AMF::Object3(name, (int)tmpi, AMF::AMF3_INTEGER);
break;
case AMF::AMF3_DOUBLE:
tmpdbl[7] = data[i + 1];
tmpdbl[6] = data[i + 2];
tmpdbl[5] = data[i + 3];
tmpdbl[4] = data[i + 4];
tmpdbl[3] = data[i + 5];
tmpdbl[2] = data[i + 6];
tmpdbl[1] = data[i + 7];
tmpdbl[0] = data[i + 8];
i += 9; // skip 8(a double)+1 forwards
d = (double *)tmpdbl;
return AMF::Object3(name, *d, AMF::AMF3_DOUBLE);
break;
case AMF::AMF3_STRING:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_STRING); // reference type
}
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)(tmpi >> 1)); // add the string data
i += (tmpi >> 1); // skip length+size+1 forwards
return AMF::Object3(name, tmpstr, AMF::AMF3_STRING); // normal type
break;
case AMF::AMF3_XMLDOC:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_XMLDOC); // reference type
}
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)(tmpi >> 1)); // add the string data
i += (tmpi >> 1); // skip length+size+1 forwards
return AMF::Object3(name, tmpstr, AMF::AMF3_XMLDOC); // normal type
break;
case AMF::AMF3_XML:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_XML); // reference type
}
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)(tmpi >> 1)); // add the string data
i += (tmpi >> 1); // skip length+size+1 forwards
return AMF::Object3(name, tmpstr, AMF::AMF3_XML); // normal type
break;
case AMF::AMF3_BYTES:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
tmpi = (tmpi << 3) >> 3; // fix sign bit
i += 5;
}
}
}
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_BYTES); // reference type
}
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)(tmpi >> 1)); // add the string data
i += (tmpi >> 1); // skip length+size+1 forwards
return AMF::Object3(name, tmpstr, AMF::AMF3_BYTES); // normal type
break;
case AMF::AMF3_DATE:
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_DATE); // reference type
}
tmpdbl[7] = data[i];
tmpdbl[6] = data[i + 1];
tmpdbl[5] = data[i + 2];
tmpdbl[4] = data[i + 3];
tmpdbl[3] = data[i + 4];
tmpdbl[2] = data[i + 5];
tmpdbl[1] = data[i + 6];
tmpdbl[0] = data[i + 7];
d = (double *)tmpdbl;
i += 8; // skip a double forwards
return AMF::Object3(name, *d, AMF::AMF3_DATE);
break;
case AMF::AMF3_ARRAY:{
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_ARRAY); // reference type
}
AMF::Object3 ret(name, AMF::AMF3_ARRAY);
arrsize = tmpi >> 1;
do{
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 4; // fix sign bit, ignore references for now...
/// \todo Fix references?
if (tmpi > 0){
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)tmpi); // add the string data
ret.addContent(
AMF::parseOne3(data, len, i, tmpstr)); // add content, recursively parsed, updating i
}
}while (tmpi > 0);
while (arrsize > 0){// while not done parsing array
ret.addContent(
AMF::parseOne3(data, len, i, "arrVal")); // add content, recursively parsed, updating i
--arrsize;
}
return ret;
}break;
case AMF::AMF3_OBJECT:{
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 3; // fix sign bit
if ((tmpi & 1) == 0){
return AMF::Object3(name, (int)((tmpi >> 1) + 1), AMF::AMF3_OBJECT); // reference type
}
AMF::Object3 ret(name, AMF::AMF3_OBJECT);
bool isdynamic = false;
if ((tmpi & 2) == 0){// traits by reference, skip for now
/// \todo Implement traits by reference. Or references in general, of course...
}else{
isdynamic = ((tmpi & 8) == 8);
arrsize = tmpi >> 4; // count of sealed members
/// \todo Read in arrsize sealed member names, then arrsize sealed members.
}
if (isdynamic){
do{
if (data[i + 1] < 0x80){
tmpi = data[i + 1];
i += 2;
}else{
tmpi = (data[i + 1] & 0x7F) << 7; // strip the upper bit, shift 7 up.
if (data[i + 2] < 0x80){
tmpi |= data[i + 2];
i += 3;
}else{
tmpi = (tmpi | (data[i + 2] & 0x7F)) << 7; // strip the upper bit, shift 7 up.
if (data[i + 3] < 0x80){
tmpi |= data[i + 3];
i += 4;
}else{
tmpi = (tmpi | (data[i + 3] & 0x7F)) << 8; // strip the upper bit, shift 7 up.
tmpi |= data[i + 4];
i += 5;
}
}
}
tmpi = (tmpi << 3) >> 4; // fix sign bit, ignore references for now...
/// \todo Fix references?
if (tmpi > 0){
tmpstr.clear(); // clean tmpstr, just to be sure
tmpstr.append((const char *)data + i, (size_t)tmpi); // add the string data
ret.addContent(
AMF::parseOne3(data, len, i, tmpstr)); // add content, recursively parsed, updating i
}
}while (tmpi > 0); // keep reading dynamic values until empty string
}// dynamic types
return ret;
}break;
}
ERROR_MSG("Error: Unimplemented AMF3 type %hhx - returning.", data[i]);
return AMF::Object3("error", AMF::AMF3_DDV_CONTAINER);
}// parseOne
/// Parses a C-string to a valid AMF::Object3.
/// This function will find all AMF3 objects in the string and return
/// them all packed in a single AMF::AMF3_DDV_CONTAINER AMF::Object3.
AMF::Object3 AMF::parse3(const unsigned char *data, unsigned int len){
AMF::Object3 ret("returned", AMF::AMF3_DDV_CONTAINER); // container type
unsigned int i = 0, j = 0;
while (i < len){
ret.addContent(AMF::parseOne3(data, len, i, ""));
if (i > j){
j = i;
}else{
return ret;
}
}
return ret;
}// parse
/// Parses a std::string to a valid AMF::Object3.
/// This function will find all AMF3 objects in the string and return
/// them all packed in a single AMF::AMF3_DDV_CONTAINER AMF::Object3.
AMF::Object3 AMF::parse3(std::string data){
return AMF::parse3((const unsigned char *)data.c_str(), data.size());
}// parse