Security-58286.270.3.0.1.tar.gz

[apple/security.git] / OSX / libsecurity_apple_csp / lib / bsafeContext.cpp

/*
 * Copyright (c) 2000-2001,2011,2014 Apple Inc. All Rights Reserved.
 * 
 * The contents of this file constitute Original Code as defined in and are
 * subject to the Apple Public Source License Version 1.2 (the 'License').
 * You may not use this file except in compliance with the License. Please obtain
 * a copy of the License at http://www.apple.com/publicsource and read it before
 * using this file.
 * 
 * This Original Code and all software distributed under the License are
 * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESS
 * OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, INCLUDING WITHOUT
 * LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR
 * PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. Please see the License for the
 * specific language governing rights and limitations under the License.
 */

#ifdef  BSAFE_CSP_ENABLE


//
// bsafeContext.cpp - implementation of class BSafe::BSafeContext
//                                        and some of its subclasses
//                              

#include "bsafecspi.h"
#include "bsafePKCS1.h"
#include <bkey.h>
#include <balg.h>
#include <algobj.h>
#include "cspdebugging.h"

#define DATA(cData)             POINTER(cData.data()), cData.length()

A_SURRENDER_CTX * const BSafe::BSafeContext::bsSurrender = NULL;


//
// Construct an algorithm object
//
BSafe::BSafeContext::BSafeContext(AppleCSPSession &session)
        : AppleCSPContext(session)
{
    bsAlgorithm = NULL;
    bsKey = NULL;
        bsBinKey = NULL;
    bsRandom = NULL;
    initialized = false;
        opStarted = false;
#ifdef SAFER
    inUpdate = NULL;
    inOutUpdate = NULL;
    inFinal = NULL;
    outFinal = NULL;
    outFinalR = NULL;
#endif //SAFER
}

BSafe::BSafeContext::~BSafeContext()
{
    reset();
}

void BSafe::BSafeContext::reset()
{
    B_DestroyAlgorithmObject(&bsAlgorithm);
    B_DestroyAlgorithmObject(&bsRandom);
        destroyBsKey();
}

/* 
 * Clear key state. We only destroy bsKey if we don't have a 
 * BinaryKey.
 */
void BSafe::BSafeContext::destroyBsKey()
{
        if(bsBinKey == NULL) {
                B_DestroyKeyObject(&bsKey);
        }
        else {
                // bsKey gets destroyed when bsBinKey gets deleted
                bsBinKey = NULL;
                bsKey = NULL;
        }
}

void BSafe::check(int status, bool isKeyOp)
{
        if(status == 0) {
                return;
        }
        dprintf1("BSAFE Error %d\n", status);
    switch (status) {
                case BE_ALLOC:
                        throw std::bad_alloc();
                case BE_SIGNATURE:
                        CssmError::throwMe(CSSMERR_CSP_VERIFY_FAILED);
                case BE_OUTPUT_LEN:
                        CssmError::throwMe(CSSMERR_CSP_OUTPUT_LENGTH_ERROR);
                case BE_INPUT_LEN:
                        CssmError::throwMe(CSSMERR_CSP_INPUT_LENGTH_ERROR);
                case BE_EXPONENT_EVEN:
                case BE_EXPONENT_LEN:
                case BE_EXPONENT_ONE:
                        CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
                case BE_DATA:
                case BE_INPUT_DATA:
                        if(isKeyOp) {
                                CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
                        }
                        else {
                                CssmError::throwMe(CSSMERR_CSP_INVALID_DATA);
                        }
                case BE_MODULUS_LEN:
                case BE_OVER_32K:
                case BE_INPUT_COUNT:
                case BE_CANCEL:
                        //@@@ later...
        default:
                        //@@@ translate BSafe errors intelligently
            CssmError::throwMe(CSSM_ERRCODE_INTERNAL_ERROR);
    }
}


void BSafe::BSafeContext::setAlgorithm(
        B_INFO_TYPE bAlgType, 
        const void *info)
{
    B_DestroyAlgorithmObject(&bsAlgorithm);     // clear any old BSafe algorithm
    check(B_CreateAlgorithmObject(&bsAlgorithm));
    check(B_SetAlgorithmInfo(bsAlgorithm, bAlgType, POINTER(info)));
}

/* safely create bsKey */
void BSafe::BSafeContext::createBsKey()
{
        /* reset to initial key state - some keys can't be reused */
    destroyBsKey();
    check(B_CreateKeyObject(&bsKey));
}

/* form of *info varies per bKeyInfo */
void BSafe::BSafeContext::setKeyAtom(
        B_INFO_TYPE bKeyInfo, 
        const void *info)
{
        /* debug only */
        if((bKeyInfo == KI_RSAPublicBER) || (bKeyInfo == KI_RSAPublic)) {
                        printf("Aargh! Unhandled KI_RSAPublic!\n");
                        CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
        }
        assert(bKeyInfo != KI_RSAPublicBER);            // handled elsewhere for now
        assert(bKeyInfo != KI_RSAPublic);                       // handled elsewhere for now
        createBsKey();
    check(B_SetKeyInfo(bsKey, bKeyInfo, POINTER(info)), true);
}

//
// Set outSize for RSA keys.
//
void BSafe::BSafeContext::setRsaOutSize(
        bool isPubKey)
{
        assert(bsKey != NULL);

        A_RSA_KEY *keyInfo;
        if(isPubKey) {
                keyInfo = getKey<A_RSA_KEY>(bsKey, KI_RSAPublic);
        }
        else {
                keyInfo = getKey<A_RSA_KEY>(bsKey, KI_RSAPrivate);
        }
        mOutSize = (B_IntegerBits(keyInfo->modulus.data, 
                keyInfo->modulus.len) + 7) / 8;
}

// 
// Handle various forms of reference key. Symmetric
// keys are stored as SymmetricBinaryKey, with raw key bytes
// in keyData. Our asymmetric keys are stored as BSafeBinaryKeys,
// with an embedded ready-to-use B_KEY_OBJ. 
// 
void BSafe::BSafeContext::setRefKey(CssmKey &key)
{
        bool isPubKey = false;
        
        switch(key.keyClass()) {
                case CSSM_KEYCLASS_SESSION_KEY:
                {
                        assert(key.blobFormat() == 
                                CSSM_KEYBLOB_REF_FORMAT_INTEGER);
                        
                        BinaryKey &binKey = session().lookupRefKey(key);
                        // fails if this is not a SymmetricBinaryKey
                        SymmetricBinaryKey *symBinKey =
                                dynamic_cast<SymmetricBinaryKey *>(&binKey);
                        if(symBinKey == NULL) {
                                errorLog0("BSafe::setRefKey(1): wrong BinaryKey subclass\n");
                                CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
                        }
                        setKeyFromCssmData(KI_Item, symBinKey->mKeyData);
                        return;
                }
                case CSSM_KEYCLASS_PUBLIC_KEY:
                        isPubKey = true;                // and fall thru
                case CSSM_KEYCLASS_PRIVATE_KEY:
                {
                        BinaryKey &binKey = session().lookupRefKey(key);
                        destroyBsKey();
                        bsBinKey = dynamic_cast<BSafeBinaryKey *>(&binKey);
                        /* this cast failing means that this is some other
                         * kind of binary key */
                        if(bsBinKey == NULL) {
                                errorLog0("BSafe::setRefKey(2): wrong BinaryKey subclass\n");
                                CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
                        }
                        assert(bsBinKey->bsKey() != NULL);
                        bsKey = bsBinKey->bsKey();
                        if(key.algorithm() == CSSM_ALGID_RSA) {
                                setRsaOutSize(isPubKey);
                        }
                        return;
                }
                default:
                    CssmError::throwMe(CSSMERR_CSP_INVALID_KEY_CLASS);
        }
}

void BSafe::BSafeContext::setKeyFromContext(
        const Context &context, 
        bool required)
{
    CssmKey &key = 
                context.get<CssmKey>(CSSM_ATTRIBUTE_KEY, CSSMERR_CSP_MISSING_ATTR_KEY);
        
        switch(key.blobType()) {
                case CSSM_KEYBLOB_REFERENCE:
                        setRefKey(key);
                        return;
                case CSSM_KEYBLOB_RAW:
                        break;          // to main routine
                default:
                        CssmError::throwMe(CSSMERR_CSP_KEY_BLOB_TYPE_INCORRECT);
        }
        
        bool isPubKey;
        switch (key.keyClass()) {
                case CSSM_KEYCLASS_SESSION_KEY:
                        /* symmetric, one format supported for all algs */
                        switch (key.blobFormat()) {
                                case CSSM_KEYBLOB_RAW_FORMAT_OCTET_STRING:
                                        setKeyFromCssmKey(KI_Item, key);
                                        return;
                                default:
                                        CssmError::throwMe(CSSMERR_CSP_INVALID_KEY_FORMAT);
                        }
                case CSSM_KEYCLASS_PUBLIC_KEY:
                        isPubKey = true;
                        break;
                case CSSM_KEYCLASS_PRIVATE_KEY:
                        isPubKey = false;
                        break;
                default:
                        CssmError::throwMe(CSSMERR_CSP_INVALID_KEY_CLASS);
        }
        
        /* We know it's an asymmetric key; get some info */
        B_INFO_TYPE infoType;
        CSSM_KEYBLOB_FORMAT expectedFormat;
        
        if(!bsafeAlgToInfoType(key.algorithm(),
                isPubKey,
                infoType, 
                expectedFormat)) {
                /* unknown alg! */
                CssmError::throwMe(CSSMERR_CSP_INVALID_KEY);
        }
        
        /* 
         * Correct format? 
         * NOTE: if we end up supporting multiple incoming key formats, they'll
         * have to be handled here.
         */
        if(expectedFormat != key.blobFormat()) {
                errorLog1("setKeyFromContext: invalid blob format (%d)\n", 
                        (int)key.blobFormat());
                CssmError::throwMe(CSSMERR_CSP_INVALID_KEY_FORMAT);
        }
        
        /*
         * Most formats can be handled directly by BSAFE. Handle the special cases 
         * requiring additional processing here. 
         */
        switch(expectedFormat)  {
                case CSSM_KEYBLOB_RAW_FORMAT_PKCS1:
                        /* RSA public keys */
                        createBsKey();
                        BS_setKeyPkcs1(CssmData::overlay(key.KeyData), bsKey);
                        break;
                default:
                        setKeyFromCssmKey(infoType, key);
                        break;
        }
        
        /* 
         * One more thing - set mOutSize for RSA keys
         */
        if(key.algorithm() == CSSM_ALGID_RSA) {
                setRsaOutSize(isPubKey);        
        }       
}

#define BSAFE_RANDSIZE  32

void BSafe::BSafeContext::setRandom()
{
    if (bsRandom == NULL) {
        check(B_CreateAlgorithmObject(&bsRandom));
        check(B_SetAlgorithmInfo(bsRandom, AI_X962Random_V0, NULL_PTR));
        check(B_RandomInit(bsRandom, chooser(), bsSurrender));
        uint8 seed[BSAFE_RANDSIZE];
                session().getRandomBytes(BSAFE_RANDSIZE, seed);
        check(B_RandomUpdate(bsRandom, seed, sizeof(seed), bsSurrender));
    }
}


//
// Operational methods of BSafeContext
//
void BSafe::BSafeContext::init(const Context &, bool)
{
    // some algorithms don't need init(), because all is done in the context constructor
}

// update for input-only block/stream algorithms
void BSafe::BSafeContext::update(const CssmData &data)
{
        opStarted = true;
    check(inUpdate(bsAlgorithm, POINTER(data.data()), data.length(), bsSurrender));
}

// update for input/output block/stream algorithms
void BSafe::BSafeContext::update(void *inp, size_t &inSize, void *outp, size_t &outSize)
{
    unsigned int length;
        opStarted = true;
    check(inOutUpdate(bsAlgorithm, POINTER(outp), &length, outSize,
                               POINTER(inp), inSize, bsRandom, bsSurrender));
    // always eat all input (inSize unchanged)
    outSize = length;

    // let the algorithm manager track I/O sizes, if needed
    trackUpdate(inSize, outSize);
}

// output-generating final call
void BSafe::BSafeContext::final(CssmData &out)
{
    unsigned int length;
    if (outFinal) {
        check(outFinal(bsAlgorithm, 
                        POINTER(out.data()), 
                        &length, 
                        out.length(), 
                        bsSurrender));
        }
    else {
        check(outFinalR(bsAlgorithm, 
                        POINTER(out.data()), 
                        &length, 
                        out.length(),
                        bsRandom, 
                        bsSurrender));
        }
    out.length(length);
        initialized = false;
}

// verifying final call (takes additional input)
void BSafe::BSafeContext::final(const CssmData &in)
{
        int status;
        
        /* note sig verify errors can show up as lots of BSAFE statuses;
         * munge them all into the appropriate error */
   if (inFinal) {
        status = inFinal(bsAlgorithm, 
                        POINTER(in.data()), 
                        in.length(), 
                        bsSurrender);
        }
    else {
        status = inFinalR(bsAlgorithm, 
                        POINTER(in.data()), 
                        in.length(), 
                        bsRandom, 
                        bsSurrender);
        }
        if(status != 0) {
                if((mType == CSSM_ALGCLASS_SIGNATURE) && (mDirection == false)) {
                        /* yep, sig verify error */
                        CssmError::throwMe(CSSMERR_CSP_VERIFY_FAILED);
                }
                /* other error, use standard trap */
                check(status);
        }
        initialized = false;
}

size_t BSafe::BSafeContext::outputSize(bool final, size_t inSize)
{
    // this default implementation only makes sense for single-output end-loaded algorithms
    return final ? mOutSize : 0;
}

void BSafe::BSafeContext::trackUpdate(size_t, size_t)
{ /* do nothing */ }

//
// Common features of CipherContexts.
//
void BSafe::CipherContext::cipherInit()
{
    // set handlers
    if (encoding) {
        inOutUpdate = B_EncryptUpdate;
        outFinalR = B_EncryptFinal;
    } else {
        inOutUpdate = B_DecryptUpdate;
        outFinalR = B_DecryptFinal;
    }
    outFinal = NULL;

    // init the algorithm
    check((encoding ? B_EncryptInit : B_DecryptInit)
          (bsAlgorithm, bsKey, chooser(), bsSurrender));

    // buffers start empty
    pending = 0;

    // state is now valid
    initialized = true;
        opStarted = false;
}
#endif  /* BSAFE_CSP_ENABLE */