#if !defined(__CONFDESCPARSER_H__) #define __CONFDESCPARSER_H__ #include #include "..\ParseTools\parsetools.h" #include #include "..\DebugTools\printhex.h" #include "..\DebugTools\hexdump.h" #include "..\DebugTools\message.h" //#include "hid.h" class UsbConfigXtracter { public: //virtual void ConfigXtract(const USB_CONFIGURATION_DESCRIPTOR *conf) = 0; //virtual void InterfaceXtract(uint8_t conf, const USB_INTERFACE_DESCRIPTOR *iface) = 0; virtual void EndpointXtract(uint8_t conf, uint8_t iface, uint8_t alt, uint8_t proto, const USB_ENDPOINT_DESCRIPTOR *ep) = 0; }; #define CP_MASK_COMPARE_CLASS 1 #define CP_MASK_COMPARE_SUBCLASS 2 #define CP_MASK_COMPARE_PROTOCOL 4 #define CP_MASK_COMPARE_ALL 7 // Configuration Descriptor Parser Class Template template class ConfigDescParser : public USBReadParser { UsbConfigXtracter *theXtractor; MultiValueBuffer theBuffer; MultiByteValueParser valParser; ByteSkipper theSkipper; uint8_t varBuffer[16 /*sizeof(USB_CONFIGURATION_DESCRIPTOR)*/]; uint8_t stateParseDescr; // ParseDescriptor state uint8_t dscrLen; // Descriptor length uint8_t dscrType; // Descriptor type bool isGoodInterface; // Apropriate interface flag uint8_t confValue; // Configuration value uint8_t protoValue; // Protocol value uint8_t ifaceNumber; // Interface number uint8_t ifaceAltSet; // Interface alternate settings bool ParseDescriptor(uint8_t **pp, uint16_t *pcntdn); void PrintHidDescriptor(const USB_HID_DESCRIPTOR *pDesc); public: ConfigDescParser(UsbConfigXtracter *xtractor); virtual void Parse(const uint16_t len, const uint8_t *pbuf, const uint16_t &offset); }; template ConfigDescParser::ConfigDescParser(UsbConfigXtracter *xtractor) : stateParseDescr(0), dscrLen(0), dscrType(0), theXtractor(xtractor) { theBuffer.pValue = varBuffer; valParser.Initialize(&theBuffer); theSkipper.Initialize(&theBuffer); }; template void ConfigDescParser::Parse(const uint16_t len, const uint8_t *pbuf, const uint16_t &offset) { uint16_t cntdn = (uint16_t)len; uint8_t *p = (uint8_t*)pbuf; while(cntdn) if (!ParseDescriptor(&p, &cntdn)) return; } template bool ConfigDescParser::ParseDescriptor(uint8_t **pp, uint16_t *pcntdn) { switch (stateParseDescr) { case 0: theBuffer.valueSize = 2; valParser.Initialize(&theBuffer); stateParseDescr = 1; case 1: if (!valParser.Parse(pp, pcntdn)) return false; dscrLen = *((uint8_t*)theBuffer.pValue); dscrType = *((uint8_t*)theBuffer.pValue + 1); stateParseDescr = 2; case 2: // This is a sort of hack. Assuming that two bytes are allready in the buffer // the pointer is positioned two bytes ahead in order for the rest of descriptor // to be read right after the size and the type fields. // This should be used carefuly. varBuffer should be used directly to handle data // in the buffer. theBuffer.pValue = varBuffer + 2; stateParseDescr = 3; case 3: switch (dscrType) { case USB_DESCRIPTOR_INTERFACE: isGoodInterface = false; case USB_DESCRIPTOR_CONFIGURATION: theBuffer.valueSize = sizeof(USB_CONFIGURATION_DESCRIPTOR) - 2; break; case USB_DESCRIPTOR_ENDPOINT: theBuffer.valueSize = sizeof(USB_ENDPOINT_DESCRIPTOR) - 2; break; case HID_DESCRIPTOR_HID: theBuffer.valueSize = dscrLen - 2; break; } valParser.Initialize(&theBuffer); stateParseDescr = 4; case 4: switch (dscrType) { case USB_DESCRIPTOR_CONFIGURATION: if (!valParser.Parse(pp, pcntdn)) return false; confValue = ((USB_CONFIGURATION_DESCRIPTOR*)varBuffer)->bConfigurationValue; break; case USB_DESCRIPTOR_INTERFACE: if (!valParser.Parse(pp, pcntdn)) return false; if ((MASK & CP_MASK_COMPARE_CLASS) && ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bInterfaceClass != CLASS_ID) break; if ((MASK & CP_MASK_COMPARE_SUBCLASS) && ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bInterfaceSubClass != SUBCLASS_ID) break; if ((MASK & CP_MASK_COMPARE_PROTOCOL) && ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bInterfaceProtocol != PROTOCOL_ID) break; isGoodInterface = true; ifaceNumber = ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bInterfaceNumber; ifaceAltSet = ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bAlternateSetting; protoValue = ((USB_INTERFACE_DESCRIPTOR*)varBuffer)->bInterfaceProtocol; break; case USB_DESCRIPTOR_ENDPOINT: if (!valParser.Parse(pp, pcntdn)) return false; if (isGoodInterface) if (theXtractor) theXtractor->EndpointXtract(confValue, ifaceNumber, ifaceAltSet, protoValue, (USB_ENDPOINT_DESCRIPTOR*)varBuffer); break; case HID_DESCRIPTOR_HID: if (!valParser.Parse(pp, pcntdn)) return false; PrintHidDescriptor((const USB_HID_DESCRIPTOR*)varBuffer); break; default: if (!theSkipper.Skip(pp, pcntdn, dscrLen-2)) return false; } theBuffer.pValue = varBuffer; stateParseDescr = 0; } return true; } template void ConfigDescParser::PrintHidDescriptor(const USB_HID_DESCRIPTOR *pDesc) { Notify(PSTR("\r\n\r\nHID Descriptor:\r\n")); Notify(PSTR("bDescLength:\t\t")); PrintHex(pDesc->bLength); Notify(PSTR("\r\nbDescriptorType:\t")); PrintHex(pDesc->bDescriptorType); Notify(PSTR("\r\nbcdHID:\t\t\t")); PrintHex(pDesc->bcdHID); Notify(PSTR("\r\nbCountryCode:\t\t")); PrintHex(pDesc->bCountryCode); Notify(PSTR("\r\nbNumDescriptors:\t")); PrintHex(pDesc->bNumDescriptors); //Notify(PSTR("\r\nbDescrType:\t\t")); //PrintHex(pDesc->bDescrType); // //Notify(PSTR("\r\nwDescriptorLength:\t")); //PrintHex(pDesc->wDescriptorLength); for (uint8_t i=0; ibNumDescriptors; i++) { HID_CLASS_DESCRIPTOR_LEN_AND_TYPE *pLT = (HID_CLASS_DESCRIPTOR_LEN_AND_TYPE*)&(pDesc->bDescrType); Notify(PSTR("\r\nbDescrType:\t\t")); PrintHex(pLT[i].bDescrType); Notify(PSTR("\r\nwDescriptorLength:\t")); PrintHex(pLT[i].wDescriptorLength); } Notify(PSTR("\r\n")); } #endif // __CONFDESCPARSER_H__