* [PATCH 1/7] CryptoPkg: Add BigNum support
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 2/7] CryptoPkg: Add BigNum API to DXE and protocol yi1 li
` (6 subsequent siblings)
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
This patch is used to add CryptBn library, which is wrapped
over OpenSSL.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
CryptoPkg/Include/Library/BaseCryptLib.h | 418 +++++++++++++
.../Library/BaseCryptLib/BaseCryptLib.inf | 1 +
CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c | 581 ++++++++++++++++++
.../Library/BaseCryptLib/Bn/CryptBnNull.c | 520 ++++++++++++++++
.../Library/BaseCryptLib/PeiCryptLib.inf | 1 +
.../Library/BaseCryptLib/SmmCryptLib.inf | 1 +
.../BaseCryptLibNull/BaseCryptLibNull.inf | 1 +
.../Library/BaseCryptLibNull/Bn/CryptBnNull.c | 520 ++++++++++++++++
8 files changed, 2043 insertions(+)
create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
create mode 100644 CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
diff --git a/CryptoPkg/Include/Library/BaseCryptLib.h b/CryptoPkg/Include/Library/BaseCryptLib.h
index 7d1499350a..b253923dd8 100644
--- a/CryptoPkg/Include/Library/BaseCryptLib.h
+++ b/CryptoPkg/Include/Library/BaseCryptLib.h
@@ -2432,4 +2432,422 @@ HkdfSha256ExtractAndExpand (
IN UINTN OutSize
);
+// =====================================================================================
+// Big number primitives
+// =====================================================================================
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumInit (
+ VOID
+ );
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ );
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+BigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ );
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+BigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ );
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+BigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ );
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+
+UINTN
+EFIAPI
+BigNumBits (
+ IN CONST VOID *Bn
+ );
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+BigNumBytes (
+ IN CONST VOID *Bn
+ );
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ );
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsOdd (
+ IN CONST VOID *Bn
+ );
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+BigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ );
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+BigNumValueOne (
+ VOID
+ );
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ );
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number.
+**/
+VOID
+EFIAPI
+BigNumConstTime (
+ IN VOID *Bn
+ );
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumNewContext (
+ VOID
+ );
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+BigNumContextFree (
+ IN VOID *BnCtx
+ );
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ );
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
#endif // __BASE_CRYPT_LIB_H__
diff --git a/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
index 3d7b917103..9e4be2fb0d 100644
--- a/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
@@ -53,6 +53,7 @@
Pk/CryptRsaPss.c
Pk/CryptRsaPssSign.c
Pem/CryptPem.c
+ Bn/CryptBn.c
SysCall/CrtWrapper.c
SysCall/TimerWrapper.c
diff --git a/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
new file mode 100644
index 0000000000..7a3043b1de
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
@@ -0,0 +1,581 @@
+/** @file Big number API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include "InternalCryptLib.h"
+#include <openssl/bn.h>
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumInit (
+ VOID
+ )
+{
+ return BN_new ();
+}
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ )
+{
+ return BN_bin2bn (Buf, (INT32)Len, NULL);
+}
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+BigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ )
+{
+ return BN_bn2bin (Bn, Buf);
+}
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+BigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ )
+{
+ if (Clear) {
+ BN_clear_free (Bn);
+ } else {
+ BN_free (Bn);
+ }
+}
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return (BOOLEAN) BN_add (BnRes, BnA, BnB);
+}
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return (BOOLEAN) BN_sub (BnRes, BnA, BnB);
+}
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_mod (BnRes, BnA, BnB, Ctx);
+ BN_CTX_free (Ctx);
+
+ return RetVal;
+}
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_mod_exp (BnRes, BnA, BnP, BnM, Ctx);
+
+ BN_CTX_free (Ctx);
+ return RetVal;
+}
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = FALSE;
+ if (BN_mod_inverse (BnRes, BnA, BnM, Ctx) != NULL) {
+ RetVal = TRUE;
+ };
+
+ BN_CTX_free (Ctx);
+ return RetVal;
+}
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_div (BnRes, NULL, BnA, BnB, Ctx);
+ BN_CTX_free (Ctx);
+
+ return RetVal;
+}
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_mod_mul (BnRes, BnA, BnB, BnM, Ctx);
+ BN_CTX_free (Ctx);
+
+ return RetVal;
+}
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+BigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ )
+{
+ return BN_cmp (BnA, BnB);
+}
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+UINTN
+EFIAPI
+BigNumBits (
+ IN CONST VOID *Bn
+ )
+{
+ return BN_num_bits (Bn);
+}
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+BigNumBytes (
+ IN CONST VOID *Bn
+ )
+{
+ return BN_num_bytes (Bn);
+}
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ )
+{
+ return (BOOLEAN) BN_is_word (Bn, Num);
+}
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsOdd (
+ IN CONST VOID *Bn
+ )
+{
+ return (BOOLEAN) BN_is_odd (Bn);
+}
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+BigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ )
+{
+ return BN_copy (BnDst, BnSrc);
+}
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+BigNumValueOne (
+ VOID
+ )
+{
+ return BN_value_one ();
+}
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ )
+{
+ return (BOOLEAN) BN_rshift (BnRes, Bn, (INT32) N);
+}
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number
+**/
+VOID
+EFIAPI
+BigNumConstTime (
+ IN VOID *Bn
+ )
+{
+ BN_set_flags (Bn, BN_FLG_CONSTTIME);
+}
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_mod_sqr (BnRes, BnA, BnM, Ctx);
+ BN_CTX_free (Ctx);
+
+ return RetVal;
+}
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumNewContext (
+ VOID
+ )
+{
+ return BN_CTX_new ();
+}
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+BigNumContextFree (
+ IN VOID *BnCtx
+ )
+{
+ BN_CTX_free (BnCtx);
+}
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ )
+{
+ return (BOOLEAN) BN_set_word (Bn, Val);
+}
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
+
+ Ctx = BN_CTX_new ();
+ if (Ctx == NULL) {
+ return FALSE;
+ }
+
+ RetVal = (BOOLEAN) BN_mod_add (BnRes, BnA, BnB, BnM, Ctx);
+ BN_CTX_free (Ctx);
+
+ return RetVal;
+}
diff --git a/CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
new file mode 100644
index 0000000000..547401fa12
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
@@ -0,0 +1,520 @@
+/** @file
+ Big number API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include <Library/BaseCryptLib.h>
+#include <Library/DebugLib.h>
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumInit (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+BigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ )
+{
+ ASSERT (FALSE);
+ return -1;
+}
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+BigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+BigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+UINTN
+EFIAPI
+BigNumBits (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+BigNumBytes (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsOdd (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+BigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+BigNumValueOne (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number
+**/
+VOID
+EFIAPI
+BigNumConstTime (
+ IN VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumNewContext (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+BigNumContextFree (
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
diff --git a/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
index 01de27e037..65ad23fb81 100644
--- a/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
@@ -60,6 +60,7 @@
Pk/CryptRsaPssSignNull.c
Pem/CryptPemNull.c
Rand/CryptRandNull.c
+ Bn/CryptBnNull.c
SysCall/CrtWrapper.c
SysCall/ConstantTimeClock.c
diff --git a/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
index 91a1715095..ce6a789dfd 100644
--- a/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
@@ -60,6 +60,7 @@
Pk/CryptRsaPss.c
Pk/CryptRsaPssSignNull.c
Pem/CryptPem.c
+ Bn/CryptBnNull.c
SysCall/CrtWrapper.c
SysCall/ConstantTimeClock.c
diff --git a/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf b/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
index 63d1d82d19..354f3d80aa 100644
--- a/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
+++ b/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
@@ -53,6 +53,7 @@
Rand/CryptRandNull.c
Pk/CryptRsaPssNull.c
Pk/CryptRsaPssSignNull.c
+ Bn/CryptBnNull.c
[Packages]
MdePkg/MdePkg.dec
diff --git a/CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c b/CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
new file mode 100644
index 0000000000..547401fa12
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
@@ -0,0 +1,520 @@
+/** @file
+ Big number API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include <Library/BaseCryptLib.h>
+#include <Library/DebugLib.h>
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumInit (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+BigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ )
+{
+ ASSERT (FALSE);
+ return -1;
+}
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+BigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+BigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+UINTN
+EFIAPI
+BigNumBits (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+BigNumBytes (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return 0;
+}
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsOdd (
+ IN CONST VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+BigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+BigNumValueOne (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number
+**/
+VOID
+EFIAPI
+BigNumConstTime (
+ IN VOID *Bn
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumNewContext (
+ VOID
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+BigNumContextFree (
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 2/7] CryptoPkg: Add BigNum API to DXE and protocol
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
2022-09-07 8:29 ` [PATCH 1/7] CryptoPkg: Add BigNum support yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 3/7] CryptoPkg: Add EC support yi1 li
` (5 subsequent siblings)
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
The implementation provides CryptBn library functions
for EFI CryptoDxe and EFI BaseCrypt Protocol.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
CryptoPkg/CryptoPkg.dsc | 1 +
CryptoPkg/Driver/Crypto.c | 520 +++++++++++++++++-
.../Pcd/PcdCryptoServiceFamilyEnable.h | 30 +
.../BaseCryptLibOnProtocolPpi/CryptLib.c | 492 +++++++++++++++++
CryptoPkg/Private/Protocol/Crypto.h | 427 ++++++++++++++
5 files changed, 1469 insertions(+), 1 deletion(-)
diff --git a/CryptoPkg/CryptoPkg.dsc b/CryptoPkg/CryptoPkg.dsc
index 50e7721f25..a766851728 100644
--- a/CryptoPkg/CryptoPkg.dsc
+++ b/CryptoPkg/CryptoPkg.dsc
@@ -168,6 +168,7 @@
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.Tls.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.TlsSet.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.TlsGet.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
+ gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.Bn.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
!endif
!if $(CRYPTO_SERVICES) == MIN_PEI
diff --git a/CryptoPkg/Driver/Crypto.c b/CryptoPkg/Driver/Crypto.c
index 76cb9f4da0..07150ad2f2 100644
--- a/CryptoPkg/Driver/Crypto.c
+++ b/CryptoPkg/Driver/Crypto.c
@@ -4582,6 +4582,498 @@ CryptoServiceParallelHash256HashAll (
return CALL_BASECRYPTLIB (ParallelHash.Services.HashAll, ParallelHash256HashAll, (Input, InputByteLen, BlockSize, Output, OutputByteLen, Customization, CustomByteLen), FALSE);
}
+// =====================================================================================
+// Big number primitives
+// =====================================================================================
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+CryptoServiceBigNumInit (
+ VOID
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Init, BigNumInit, (), NULL);
+}
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+CryptoServiceBigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.FromBin, BigNumFromBin, (Buf, Len), NULL);
+}
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+CryptoServiceBigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.ToBin, BigNumToBin, (Bn, Buf), -1);
+}
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+CryptoServiceBigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Bn.Services.Free, BigNumFree, (Bn, Clear));
+}
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Add, BigNumAdd, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Sub, BigNumSub, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Mod, BigNumMod, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized.
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.ExpMod, BigNumExpMod, (BnA, BnP, BnM, BnRes), FALSE);
+}
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.InverseMod, BigNumInverseMod, (BnA, BnM, BnRes), FALSE);
+}
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Div, BigNumDiv, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.MulMod, BigNumMulMod, (BnA, BnB, BnM, BnRes), FALSE);
+}
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+CryptoServiceBigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Cmp, BigNumCmp, (BnA, BnB), 0);
+}
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+UINTN
+EFIAPI
+CryptoServiceBigNumBits (
+ IN CONST VOID *Bn
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Bits, BigNumBits, (Bn), 0);
+}
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+CryptoServiceBigNumBytes (
+ IN CONST VOID *Bn
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Bytes, BigNumBytes, (Bn), 0);
+}
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.IsWord, BigNumIsWord, (Bn, Num), FALSE);
+}
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumIsOdd (
+ IN CONST VOID *Bn
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.IsOdd, BigNumIsOdd, (Bn), FALSE);
+}
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+CryptoServiceBigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.Copy, BigNumCopy, (BnDst, BnSrc), NULL);
+}
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+CryptoServiceBigNumValueOne (
+ VOID
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.ValueOne, BigNumValueOne, (), NULL);
+}
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.RShift, BigNumRShift, (Bn, N, BnRes), FALSE);
+}
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number.
+**/
+VOID
+EFIAPI
+CryptoServiceBigNumConstTime (
+ IN VOID *Bn
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Bn.Services.ConstTime, BigNumConstTime, (Bn));
+}
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.SqrMod, BigNumSqrMod, (BnA, BnM, BnRes), FALSE);
+}
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+CryptoServiceBigNumNewContext (
+ VOID
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.NewContext, BigNumNewContext, (), NULL);
+}
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+CryptoServiceBigNumContextFree (
+ IN VOID *BnCtx
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Bn.Services.ContextFree, BigNumContextFree, (BnCtx));
+}
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.SetUint, BigNumSetUint, (Bn, Val), FALSE);
+}
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceBigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ return CALL_BASECRYPTLIB (Bn.Services.AddMod, BigNumAddMod, (BnA, BnB, BnM, BnRes), FALSE);
+}
+
const EDKII_CRYPTO_PROTOCOL mEdkiiCrypto = {
/// Version
CryptoServiceGetCryptoVersion,
@@ -4787,5 +5279,31 @@ const EDKII_CRYPTO_PROTOCOL mEdkiiCrypto = {
CryptoServiceRsaPssSign,
CryptoServiceRsaPssVerify,
/// Parallel hash
- CryptoServiceParallelHash256HashAll
+ CryptoServiceParallelHash256HashAll,
+ /// Big Numbers
+ CryptoServiceBigNumInit,
+ CryptoServiceBigNumFromBin,
+ CryptoServiceBigNumToBin,
+ CryptoServiceBigNumFree,
+ CryptoServiceBigNumAdd,
+ CryptoServiceBigNumSub,
+ CryptoServiceBigNumMod,
+ CryptoServiceBigNumExpMod,
+ CryptoServiceBigNumInverseMod,
+ CryptoServiceBigNumDiv,
+ CryptoServiceBigNumMulMod,
+ CryptoServiceBigNumCmp,
+ CryptoServiceBigNumBits,
+ CryptoServiceBigNumBytes,
+ CryptoServiceBigNumIsWord,
+ CryptoServiceBigNumIsOdd,
+ CryptoServiceBigNumCopy,
+ CryptoServiceBigNumValueOne,
+ CryptoServiceBigNumRShift,
+ CryptoServiceBigNumConstTime,
+ CryptoServiceBigNumSqrMod,
+ CryptoServiceBigNumNewContext,
+ CryptoServiceBigNumContextFree,
+ CryptoServiceBigNumSetUint,
+ CryptoServiceBigNumAddMod,
};
diff --git a/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h b/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
index 3d53c2f105..1b3c9d8f52 100644
--- a/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
+++ b/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
@@ -301,6 +301,36 @@ typedef struct {
} Services;
UINT32 Family;
} ParallelHash;
+ union {
+ struct {
+ UINT8 Init : 1;
+ UINT8 FromBin : 1;
+ UINT8 ToBin : 1;
+ UINT8 Free : 1;
+ UINT8 Add : 1;
+ UINT8 Sub : 1;
+ UINT8 Mod : 1;
+ UINT8 ExpMod : 1;
+ UINT8 InverseMod : 1;
+ UINT8 Div : 1;
+ UINT8 MulMod : 1;
+ UINT8 Cmp : 1;
+ UINT8 Bits : 1;
+ UINT8 Bytes : 1;
+ UINT8 IsWord : 1;
+ UINT8 IsOdd : 1;
+ UINT8 Copy : 1;
+ UINT8 ValueOne : 1;
+ UINT8 RShift : 1;
+ UINT8 ConstTime : 1;
+ UINT8 SqrMod : 1;
+ UINT8 NewContext : 1;
+ UINT8 ContextFree : 1;
+ UINT8 SetUint : 1;
+ UINT8 AddMod : 1;
+ } Services;
+ UINT32 Family;
+ } Bn;
} PCD_CRYPTO_SERVICE_FAMILY_ENABLE;
#endif
diff --git a/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c b/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
index 8ee1b53cf9..c5d71b5269 100644
--- a/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
+++ b/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
@@ -3612,3 +3612,495 @@ TlsGetCertRevocationList (
{
CALL_CRYPTO_SERVICE (TlsGetCertRevocationList, (Data, DataSize), EFI_UNSUPPORTED);
}
+
+// =====================================================================================
+// Big number primitive
+// =====================================================================================
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumInit (
+ VOID
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumInit, (), NULL);
+}
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumFromBin (
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumFromBin, (Buf, Len), NULL);
+}
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least BigNumBytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+INTN
+EFIAPI
+BigNumToBin (
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumToBin, (Bn, Buf), -1);
+}
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+VOID
+EFIAPI
+BigNumFree (
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (BigNumFree, (Bn, Clear));
+}
+
+/**
+ Calculate the sum of two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAdd (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumAdd, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Subtract two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSub (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumSub, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Calculate remainder: BnRes = BnA % BnB
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumMod, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of (BnA ^ BnP) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumExpMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumExpMod, (BnA, BnP, BnM, BnRes), FALSE);
+}
+
+/**
+ Compute BnA inverse modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumInverseMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumInverseMod, (BnA, BnM, BnRes), FALSE);
+}
+
+/**
+ Divide two Big Numbers.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumDiv (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumDiv, (BnA, BnB, BnRes), FALSE);
+}
+
+/**
+ Multiply two Big Numbers modulo BnM.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumMulMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumMulMod, (BnA, BnB, BnM, BnRes), FALSE);
+}
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+INTN
+EFIAPI
+BigNumCmp (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumCmp, (BnA, BnB), 0);
+}
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+UINTN
+EFIAPI
+BigNumBits (
+ IN CONST VOID *Bn
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumBits, (Bn), 0);
+}
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+UINTN
+EFIAPI
+BigNumBytes (
+ IN CONST VOID *Bn
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumBytes, (Bn), 0);
+}
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsWord (
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumIsWord, (Bn, Num), FALSE);
+}
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumIsOdd (
+ IN CONST VOID *Bn
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumIsOdd, (Bn), FALSE);
+}
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+VOID *
+EFIAPI
+BigNumCopy (
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumCopy, (BnDst, BnSrc), NULL);
+}
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+CONST VOID *
+EFIAPI
+BigNumValueOne (
+ VOID
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumValueOne, (), NULL);
+}
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumRShift (
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumRShift, (Bn, N, BnRes), FALSE);
+}
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number.
+**/
+VOID
+EFIAPI
+BigNumConstTime (
+ IN VOID *Bn
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (BigNumConstTime, (Bn));
+}
+
+/**
+ Calculate square modulo.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSqrMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumSqrMod, (BnA, BnM, BnRes), FALSE);
+}
+
+/**
+ Create new Big Number computation context. This is an opaque structure
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+VOID *
+EFIAPI
+BigNumNewContext (
+ VOID
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumNewContext, (), NULL);
+}
+
+/**
+ Free Big Number context that was allocated with BigNumNewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+VOID
+EFIAPI
+BigNumContextFree (
+ IN VOID *BnCtx
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (BigNumContextFree, (BnCtx));
+}
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumSetUint (
+ IN VOID *Bn,
+ IN UINTN Val
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumSetUint, (Bn, Val), FALSE);
+}
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+BigNumAddMod (
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ )
+{
+ CALL_CRYPTO_SERVICE (BigNumAddMod, (BnA, BnB, BnM, BnRes), FALSE);
+}
diff --git a/CryptoPkg/Private/Protocol/Crypto.h b/CryptoPkg/Private/Protocol/Crypto.h
index c417568e96..ec3cba8e93 100644
--- a/CryptoPkg/Private/Protocol/Crypto.h
+++ b/CryptoPkg/Private/Protocol/Crypto.h
@@ -3486,6 +3486,407 @@ BOOLEAN
IN UINTN CustomByteLen
);
+// =====================================================================================
+// Big Number Primitive
+// =====================================================================================
+
+/**
+ Allocate new Big Number.
+
+ @retval New BigNum opaque structure or NULL on failure.
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_BIGNUM_INIT)(
+ VOID
+ );
+
+/**
+ Allocate new Big Number and assign the provided value to it.
+
+ @param[in] Buf Big endian encoded buffer.
+ @param[in] Len Buffer length.
+
+ @retval New EDKII_CRYPTO_BIGNUM_ opaque structure or NULL on failure.
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_BIGNUM_FROM_BIN)(
+ IN CONST UINT8 *Buf,
+ IN UINTN Len
+ );
+
+/**
+ Convert the absolute value of Bn into big-endian form and store it at Buf.
+ The Buf array should have at least EDKII_CRYPTO_BIGNUM_Bytes() in it.
+
+ @param[in] Bn Big number to convert.
+ @param[out] Buf Output buffer.
+
+ @retval The length of the big-endian number placed at Buf or -1 on error.
+**/
+typedef
+INTN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_TO_BIN)(
+ IN CONST VOID *Bn,
+ OUT UINT8 *Buf
+ );
+
+/**
+ Free the Big Number.
+
+ @param[in] Bn Big number to free.
+ @param[in] Clear TRUE if the buffer should be cleared.
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_BIGNUM_FREE)(
+ IN VOID *Bn,
+ IN BOOLEAN Clear
+ );
+
+/**
+ Calculate the sum of two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA + BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_ADD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Subtract two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA - BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_SUB)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Calculate remainder: BnRes = BnA % BnB.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result of BnA % BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compute BnA to the BnP-th power modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnP Big number (power).
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result of BnA ^ BnP % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_EXP_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnP,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compute BnA inverse modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnRes) % BnM == 1.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_INVERSE_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Divide two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[out] BnRes The result, such that BnA / BnB.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_DIV)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ OUT VOID *BnRes
+ );
+
+/**
+ Multiply two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA * BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_MUL_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Compare two Big Numbers.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+
+ @retval 0 BnA == BnB.
+ @retval 1 BnA > BnB.
+ @retval -1 BnA < BnB.
+**/
+typedef
+INTN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_CMP)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB
+ );
+
+/**
+ Get number of bits in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bits.
+**/
+typedef
+UINTN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_BITS)(
+ IN CONST VOID *Bn
+ );
+
+/**
+ Get number of bytes in Bn.
+
+ @param[in] Bn Big number.
+
+ @retval Number of bytes.
+**/
+typedef
+UINTN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_BYTES)(
+ IN CONST VOID *Bn
+ );
+
+/**
+ Checks if Big Number equals to the given Num.
+
+ @param[in] Bn Big number.
+ @param[in] Num Number.
+
+ @retval TRUE iff Bn == Num.
+ @retval FALSE otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_IS_WORD)(
+ IN CONST VOID *Bn,
+ IN UINTN Num
+ );
+
+/**
+ Checks if Big Number is odd.
+
+ @param[in] Bn Big number.
+
+ @retval TRUE Bn is odd (Bn % 2 == 1).
+ @retval FALSE otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_IS_ODD)(
+ IN CONST VOID *Bn
+ );
+
+/**
+ Copy Big number.
+
+ @param[out] BnDst Destination.
+ @param[in] BnSrc Source.
+
+ @retval BnDst on success.
+ @retval NULL otherwise.
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_BIGNUM_COPY)(
+ OUT VOID *BnDst,
+ IN CONST VOID *BnSrc
+ );
+
+/**
+ Get constant Big number with value of "1".
+ This may be used to save expensive allocations.
+
+ @retval Big Number with value of 1.
+**/
+typedef
+CONST VOID *
+(EFIAPI *EDKII_CRYPTO_BIGNUM_VALUE_ONE)(
+ VOID
+ );
+
+/**
+ Shift right Big Number.
+ Please note, all "out" Big number arguments should be properly initialized
+ by calling to BigNumInit() or BigNumFromBin() functions.
+
+ @param[in] Bn Big number.
+ @param[in] N Number of bits to shift.
+ @param[out] BnRes The result.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_R_SHIFT)(
+ IN CONST VOID *Bn,
+ IN UINTN N,
+ OUT VOID *BnRes
+ );
+
+/**
+ Mark Big Number for constant time computations.
+ This function should be called before any constant time computations are
+ performed on the given Big number.
+
+ @param[in] Bn Big number.
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_BIGNUM_CONST_TIME)(
+ IN VOID *Bn
+ );
+
+/**
+ Calculate square modulo.
+
+ @param[in] BnA Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA ^ 2) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_SQR_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
+/**
+ Create new Big Number computation context. This is an opaque structure.
+ which should be passed to any function that requires it. The BN context is
+ needed to optimize calculations and expensive allocations.
+
+ @retval Big Number context struct or NULL on failure.
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_BIGNUM_NEW_CONTEXT)(
+ VOID
+ );
+
+/**
+ Free Big Number context that was allocated with EDKII_CRYPTO_BIGNUM_NewContext().
+
+ @param[in] BnCtx Big number context to free.
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_BIGNUM_CONTEXT_FREE)(
+ IN VOID *BnCtx
+ );
+
+/**
+ Set Big Number to a given value.
+
+ @param[in] Bn Big number to set.
+ @param[in] Val Value to set.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_SET_UINT)(
+ IN VOID *Bn,
+ IN UINTN Val
+ );
+
+/**
+ Add two Big Numbers modulo BnM.
+
+ @param[in] BnA Big number.
+ @param[in] BnB Big number.
+ @param[in] BnM Big number (modulo).
+ @param[out] BnRes The result, such that (BnA + BnB) % BnM.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_BIGNUM_ADD_MOD)(
+ IN CONST VOID *BnA,
+ IN CONST VOID *BnB,
+ IN CONST VOID *BnM,
+ OUT VOID *BnRes
+ );
+
///
/// EDK II Crypto Protocol
///
@@ -3675,6 +4076,32 @@ struct _EDKII_CRYPTO_PROTOCOL {
EDKII_CRYPTO_RSA_PSS_VERIFY RsaPssVerify;
/// Parallel hash
EDKII_CRYPTO_PARALLEL_HASH_ALL ParallelHash256HashAll;
+ /// Big Number
+ EDKII_CRYPTO_BIGNUM_INIT BigNumInit;
+ EDKII_CRYPTO_BIGNUM_FROM_BIN BigNumFromBin;
+ EDKII_CRYPTO_BIGNUM_TO_BIN BigNumToBin;
+ EDKII_CRYPTO_BIGNUM_FREE BigNumFree;
+ EDKII_CRYPTO_BIGNUM_ADD BigNumAdd;
+ EDKII_CRYPTO_BIGNUM_SUB BigNumSub;
+ EDKII_CRYPTO_BIGNUM_MOD BigNumMod;
+ EDKII_CRYPTO_BIGNUM_EXP_MOD BigNumExpMod;
+ EDKII_CRYPTO_BIGNUM_INVERSE_MOD BigNumInverseMod;
+ EDKII_CRYPTO_BIGNUM_DIV BigNumDiv;
+ EDKII_CRYPTO_BIGNUM_MUL_MOD BigNumMulMod;
+ EDKII_CRYPTO_BIGNUM_CMP BigNumCmp;
+ EDKII_CRYPTO_BIGNUM_BITS BigNumBits;
+ EDKII_CRYPTO_BIGNUM_BYTES BigNumBytes;
+ EDKII_CRYPTO_BIGNUM_IS_WORD BigNumIsWord;
+ EDKII_CRYPTO_BIGNUM_IS_ODD BigNumIsOdd;
+ EDKII_CRYPTO_BIGNUM_COPY BigNumCopy;
+ EDKII_CRYPTO_BIGNUM_VALUE_ONE BigNumValueOne;
+ EDKII_CRYPTO_BIGNUM_R_SHIFT BigNumRShift;
+ EDKII_CRYPTO_BIGNUM_CONST_TIME BigNumConstTime;
+ EDKII_CRYPTO_BIGNUM_SQR_MOD BigNumSqrMod;
+ EDKII_CRYPTO_BIGNUM_NEW_CONTEXT BigNumNewContext;
+ EDKII_CRYPTO_BIGNUM_CONTEXT_FREE BigNumContextFree;
+ EDKII_CRYPTO_BIGNUM_SET_UINT BigNumSetUint;
+ EDKII_CRYPTO_BIGNUM_ADD_MOD BigNumAddMod;
};
extern GUID gEdkiiCryptoProtocolGuid;
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 3/7] CryptoPkg: Add EC support
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
2022-09-07 8:29 ` [PATCH 1/7] CryptoPkg: Add BigNum support yi1 li
2022-09-07 8:29 ` [PATCH 2/7] CryptoPkg: Add BigNum API to DXE and protocol yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 4/7] CryptoPkg: Add EC APIs to DXE and protocol yi1 li
` (4 subsequent siblings)
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
This patch is used to add CryptEc library, which is wrapped
over OpenSSL.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
CryptoPkg/Include/Library/BaseCryptLib.h | 424 ++++++++++
.../Library/BaseCryptLib/BaseCryptLib.inf | 2 +
.../Library/BaseCryptLib/PeiCryptLib.inf | 1 +
CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c | 755 ++++++++++++++++++
.../Library/BaseCryptLib/Pk/CryptEcNull.c | 496 ++++++++++++
.../Library/BaseCryptLib/SmmCryptLib.inf | 1 +
.../BaseCryptLibNull/BaseCryptLibNull.inf | 1 +
.../Library/BaseCryptLibNull/Pk/CryptEcNull.c | 496 ++++++++++++
8 files changed, 2176 insertions(+)
create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
create mode 100644 CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
diff --git a/CryptoPkg/Include/Library/BaseCryptLib.h b/CryptoPkg/Include/Library/BaseCryptLib.h
index b253923dd8..ea3ed5270f 100644
--- a/CryptoPkg/Include/Library/BaseCryptLib.h
+++ b/CryptoPkg/Include/Library/BaseCryptLib.h
@@ -14,6 +14,13 @@ SPDX-License-Identifier: BSD-2-Clause-Patent
#include <Uefi/UefiBaseType.h>
+#define CRYPTO_NID_NULL 0x0000
+
+// Key Exchange
+#define CRYPTO_NID_SECP256R1 0x0204
+#define CRYPTO_NID_SECP384R1 0x0205
+#define CRYPTO_NID_SECP521R1 0x0206
+
///
/// MD5 digest size in bytes
///
@@ -2850,4 +2857,421 @@ BigNumAddMod (
OUT VOID *BnRes
);
+// =====================================================================================
+// Basic Elliptic Curve Primitives
+// =====================================================================================
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcGroupInit (
+ IN UINTN CryptoNid
+ );
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient.
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ );
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+EcGroupFree (
+ IN VOID *EcGroup
+ );
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcPointInit (
+ IN CONST VOID *EcGroup
+ );
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+EcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ );
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ );
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ );
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ );
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ );
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ );
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ );
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ );
+
+// =====================================================================================
+// Elliptic Curve Diffie Hellman Primitives
+// =====================================================================================
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+EcNewByNid (
+ IN UINTN Nid
+ );
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+EcFree (
+ IN VOID *EcContext
+ );
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ );
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+EcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ );
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ );
+
#endif // __BASE_CRYPT_LIB_H__
diff --git a/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
index 9e4be2fb0d..ade6ee3fdd 100644
--- a/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/BaseCryptLib.inf
@@ -52,6 +52,8 @@
Pk/CryptTs.c
Pk/CryptRsaPss.c
Pk/CryptRsaPssSign.c
+ Pk/CryptEcNull.c |*|*|*|!gEfiCryptoPkgTokenSpaceGuid.PcdOpensslEcEnabled
+ Pk/CryptEc.c |*|*|*|gEfiCryptoPkgTokenSpaceGuid.PcdOpensslEcEnabled
Pem/CryptPem.c
Bn/CryptBn.c
diff --git a/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
index 65ad23fb81..383df2b23c 100644
--- a/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/PeiCryptLib.inf
@@ -58,6 +58,7 @@
Pk/CryptTsNull.c
Pk/CryptRsaPss.c
Pk/CryptRsaPssSignNull.c
+ Pk/CryptEcNull.c
Pem/CryptPemNull.c
Rand/CryptRandNull.c
Bn/CryptBnNull.c
diff --git a/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
new file mode 100644
index 0000000000..e9b0391a56
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
@@ -0,0 +1,755 @@
+/** @file
+ Elliptic Curve and ECDH API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include "InternalCryptLib.h"
+#include <openssl/objects.h>
+#include <openssl/bn.h>
+#include <openssl/ec.h>
+
+// =====================================================================================
+// Basic Elliptic Curve Primitives
+// =====================================================================================
+
+/**
+ Return the Nid of certain ECC curve.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval !=-1 On success.
+ @retval -1 ECC curve not supported.
+**/
+STATIC
+INT32
+CryptoNidToOpensslNid (
+ IN UINTN CryptoNid
+)
+{
+ INT32 Nid;
+
+ switch (CryptoNid) {
+ case CRYPTO_NID_SECP256R1:
+ Nid = NID_X9_62_prime256v1;
+ break;
+ case CRYPTO_NID_SECP384R1:
+ Nid = NID_secp384r1;
+ break;
+ case CRYPTO_NID_SECP521R1:
+ Nid = NID_secp521r1;
+ break;
+ default:
+ return -1;
+ }
+
+ return Nid;
+}
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcGroupInit (
+ IN UINTN CryptoNid
+ )
+{
+ INT32 Nid;
+
+ Nid = CryptoNidToOpensslNid (CryptoNid);
+
+ if (Nid < 0) {
+ return NULL;
+ }
+
+ return EC_GROUP_new_by_curve_name (Nid);
+}
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient..
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_GROUP_get_curve (EcGroup, BnPrime, BnA, BnB, BnCtx);
+}
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ )
+{
+ return (BOOLEAN) EC_GROUP_get_order (EcGroup, BnOrder, NULL);
+}
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+EcGroupFree (
+ IN VOID *EcGroup
+ )
+{
+ EC_GROUP_free (EcGroup);
+}
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcPointInit (
+ IN CONST VOID *EcGroup
+ )
+{
+ return EC_POINT_new (EcGroup);
+}
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+EcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ )
+{
+ if (Clear) {
+ EC_POINT_clear_free (EcPoint);
+ } else {
+ EC_POINT_free (EcPoint);
+ }
+}
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_get_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
+}
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_set_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
+}
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_add (EcGroup, EcPointResult, EcPointA, EcPointB, BnCtx);
+}
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_mul (EcGroup, EcPointResult, NULL, EcPoint, BnPScalar, BnCtx);
+}
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_invert (EcGroup, EcPoint, BnCtx);
+}
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ return EC_POINT_is_on_curve (EcGroup, EcPoint, BnCtx) == 1;
+}
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ )
+{
+ return EC_POINT_is_at_infinity (EcGroup, EcPoint) == 1;
+}
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ return EC_POINT_cmp (EcGroup, EcPointA, EcPointB, BnCtx) == 0;
+}
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ )
+{
+ return (BOOLEAN) EC_POINT_set_compressed_coordinates (EcGroup, EcPoint, BnX, YBit, BnCtx);
+}
+
+// =====================================================================================
+// Elliptic Curve Diffie Hellman Primitives
+// =====================================================================================
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+EcNewByNid (
+ IN UINTN Nid
+ )
+{
+ INT32 OpenSslNid;
+
+ OpenSslNid = CryptoNidToOpensslNid (Nid);
+ if (OpenSslNid < 0) {
+ return NULL;
+ }
+
+ return (VOID *)EC_KEY_new_by_curve_name (OpenSslNid);
+}
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+EcFree (
+ IN VOID *EcContext
+ )
+{
+ EC_KEY_free ((EC_KEY *) EcContext);
+}
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ EC_KEY *EcKey;
+ CONST EC_GROUP *Group;
+ CONST EC_POINT *EcPoint;
+ BOOLEAN RetVal;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ UINTN HalfSize;
+ INTN XSize;
+ INTN YSize;
+
+ if (EcContext == NULL || PublicKeySize == NULL) {
+ return FALSE;
+ }
+
+ if (PublicKey == NULL && *PublicKeySize != 0) {
+ return FALSE;
+ }
+
+ EcKey = (EC_KEY *)EcContext;
+ Group = EC_KEY_get0_group (EcKey);
+ HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
+
+ // Assume RAND_seed was called
+ if (EC_KEY_generate_key (EcKey) != 1) {
+ return FALSE;
+ }
+
+ if (*PublicKeySize < HalfSize * 2) {
+ *PublicKeySize = HalfSize * 2;
+ return FALSE;
+ }
+ *PublicKeySize = HalfSize * 2;
+
+ EcPoint = EC_KEY_get0_public_key (EcKey);
+ if (EcPoint == NULL) {
+ return FALSE;
+ }
+
+ RetVal = FALSE;
+ BnX = BN_new();
+ BnY = BN_new();
+ if (BnX == NULL || BnY == NULL) {
+ goto fail;
+ }
+
+ if (EC_POINT_get_affine_coordinates (Group, EcPoint, BnX, BnY, NULL) != 1) {
+ goto fail;
+ }
+
+ XSize = BN_num_bytes (BnX);
+ YSize = BN_num_bytes (BnY);
+ if (XSize <= 0 || YSize <= 0) {
+ goto fail;
+ }
+ ASSERT ((UINTN)XSize <= HalfSize && (UINTN)YSize <= HalfSize);
+
+ ZeroMem (PublicKey, *PublicKeySize);
+ BN_bn2bin (BnX, &PublicKey[0 + HalfSize - XSize]);
+ BN_bn2bin (BnY, &PublicKey[HalfSize + HalfSize - YSize]);
+
+ RetVal = TRUE;
+
+fail:
+ BN_free (BnX);
+ BN_free (BnY);
+ return RetVal;
+}
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+EcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ EC_KEY *EcKey;
+ CONST EC_GROUP *Group;
+ CONST EC_POINT *EcPoint;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ UINTN HalfSize;
+ INTN XSize;
+ INTN YSize;
+ BOOLEAN RetVal;
+
+ if (EcContext == NULL || PublicKeySize == NULL) {
+ return FALSE;
+ }
+
+ if (PublicKey == NULL && *PublicKeySize != 0) {
+ return FALSE;
+ }
+
+ EcKey = (EC_KEY *)EcContext;
+ Group = EC_KEY_get0_group (EcKey);
+ HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
+ if (*PublicKeySize < HalfSize * 2) {
+ *PublicKeySize = HalfSize * 2;
+ return FALSE;
+ }
+ *PublicKeySize = HalfSize * 2;
+
+ EcPoint = EC_KEY_get0_public_key (EcKey);
+ if (EcPoint == NULL) {
+ return FALSE;
+ }
+
+ RetVal = FALSE;
+ BnX = BN_new();
+ BnY = BN_new();
+ if (BnX == NULL || BnY == NULL) {
+ goto fail;
+ }
+
+ if (EC_POINT_get_affine_coordinates (Group, EcPoint, BnX, BnY, NULL) != 1) {
+ goto fail;
+ }
+
+ XSize = BN_num_bytes (BnX);
+ YSize = BN_num_bytes (BnY);
+ if (XSize <= 0 || YSize <= 0) {
+ goto fail;
+ }
+ ASSERT ((UINTN)XSize <= HalfSize && (UINTN)YSize <= HalfSize);
+
+ if (PublicKey != NULL) {
+ ZeroMem (PublicKey, *PublicKeySize);
+ BN_bn2bin (BnX, &PublicKey[0 + HalfSize - XSize]);
+ BN_bn2bin (BnY, &PublicKey[HalfSize + HalfSize - YSize]);
+ }
+
+ RetVal = TRUE;
+
+fail:
+ BN_free (BnX);
+ BN_free (BnY);
+ return RetVal;
+}
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If public key is compressed, the PeerPublic will only contain half key (X).
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ )
+{
+ EC_KEY *EcKey;
+ EC_KEY *PeerEcKey;
+ CONST EC_GROUP *Group;
+ BOOLEAN RetVal;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ EC_POINT *Point;
+ INT32 OpenSslNid;
+ UINTN HalfSize;
+
+ if (EcContext == NULL || PeerPublic == NULL || KeySize == NULL) {
+ return FALSE;
+ }
+
+ if (Key == NULL && *KeySize != 0) {
+ return FALSE;
+ }
+
+ if (PeerPublicSize > INT_MAX) {
+ return FALSE;
+ }
+
+ EcKey = (EC_KEY *) EcContext;
+ Group = EC_KEY_get0_group (EcKey);
+ HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
+ if (CompressFlag == NULL && PeerPublicSize != HalfSize * 2) {
+ return FALSE;
+ }
+ if (CompressFlag != NULL && PeerPublicSize != HalfSize) {
+ return FALSE;
+ }
+ if (*KeySize < HalfSize) {
+ *KeySize = HalfSize;
+ return FALSE;
+ }
+ *KeySize = HalfSize;
+
+ RetVal = FALSE;
+ Point = NULL;
+ BnX = BN_bin2bn (PeerPublic, (INT32) HalfSize, NULL);
+ BnY = NULL;
+ Point = EC_POINT_new (Group);
+ PeerEcKey = NULL;
+ if (BnX == NULL || Point == NULL) {
+ goto fail;
+ }
+
+ if (CompressFlag == NULL) {
+ BnY = BN_bin2bn (PeerPublic + HalfSize, (INT32) HalfSize, NULL);
+ if (BnY == NULL) {
+ goto fail;
+ }
+ if (EC_POINT_set_affine_coordinates (Group, Point, BnX, BnY, NULL) != 1) {
+ goto fail;
+ }
+ } else {
+ if (EC_POINT_set_compressed_coordinates (Group, Point, BnX, *CompressFlag, NULL) != 1) {
+ goto fail;
+ }
+ }
+
+ // Validate NIST ECDH public key
+ OpenSslNid = EC_GROUP_get_curve_name (Group);
+ PeerEcKey = EC_KEY_new_by_curve_name (OpenSslNid);
+ if (PeerEcKey == NULL) {
+ goto fail;
+ }
+ if (EC_KEY_set_public_key (PeerEcKey, Point) != 1) {
+ goto fail;
+ }
+ if (EC_KEY_check_key (PeerEcKey) != 1) {
+ goto fail;
+ }
+
+ if (ECDH_compute_key (Key, *KeySize, Point, EcKey, NULL) <= 0) {
+ goto fail;
+ }
+
+ RetVal = TRUE;
+
+fail:
+ BN_free (BnX);
+ BN_free (BnY);
+ EC_POINT_free(Point);
+ EC_KEY_free (PeerEcKey);
+ return RetVal;
+}
diff --git a/CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
new file mode 100644
index 0000000000..d9f1004f6c
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
@@ -0,0 +1,496 @@
+/** @file
+ Elliptic Curve and ECDH API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include <Library/BaseCryptLib.h>
+#include <Library/DebugLib.h>
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcGroupInit (
+ IN UINTN CryptoNid
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient..
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+EcGroupFree (
+ IN VOID *EcGroup
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcPointInit (
+ IN CONST VOID *EcGroup
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+EcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+EcNewByNid (
+ IN UINTN Nid
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+EcFree (
+ IN VOID *EcContext
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+EcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
diff --git a/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
index ce6a789dfd..4bc3063485 100644
--- a/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/SmmCryptLib.inf
@@ -59,6 +59,7 @@
Pk/CryptTsNull.c
Pk/CryptRsaPss.c
Pk/CryptRsaPssSignNull.c
+ Pk/CryptEcNull.c
Pem/CryptPem.c
Bn/CryptBnNull.c
diff --git a/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf b/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
index 354f3d80aa..e1a57ef09f 100644
--- a/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
+++ b/CryptoPkg/Library/BaseCryptLibNull/BaseCryptLibNull.inf
@@ -49,6 +49,7 @@
Pk/CryptX509Null.c
Pk/CryptAuthenticodeNull.c
Pk/CryptTsNull.c
+ Pk/CryptEcNull.c
Pem/CryptPemNull.c
Rand/CryptRandNull.c
Pk/CryptRsaPssNull.c
diff --git a/CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c b/CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
new file mode 100644
index 0000000000..d9f1004f6c
--- /dev/null
+++ b/CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
@@ -0,0 +1,496 @@
+/** @file
+ Elliptic Curve and ECDH API implementation based on OpenSSL
+
+ Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+ SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include <Library/BaseCryptLib.h>
+#include <Library/DebugLib.h>
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcGroupInit (
+ IN UINTN CryptoNid
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient..
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+EcGroupFree (
+ IN VOID *EcGroup
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcPointInit (
+ IN CONST VOID *EcGroup
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+EcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+EcNewByNid (
+ IN UINTN Nid
+ )
+{
+ ASSERT (FALSE);
+ return NULL;
+}
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+EcFree (
+ IN VOID *EcContext
+ )
+{
+ ASSERT (FALSE);
+}
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+EcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ )
+{
+ ASSERT (FALSE);
+ return FALSE;
+}
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 4/7] CryptoPkg: Add EC APIs to DXE and protocol
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
` (2 preceding siblings ...)
2022-09-07 8:29 ` [PATCH 3/7] CryptoPkg: Add EC support yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 5/7] CryptoPkg/Test: Add unit test for CryptoBn yi1 li
` (3 subsequent siblings)
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
The implementation provides CryptEc library functions
for EFI Driveer and EFI BaseCrypt Protocol.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
CryptoPkg/CryptoPkg.dsc | 1 +
CryptoPkg/Driver/Crypto.c | 496 ++++++++++++++++++
.../Pcd/PcdCryptoServiceFamilyEnable.h | 25 +
.../BaseCryptLibOnProtocolPpi/CryptLib.c | 469 +++++++++++++++++
CryptoPkg/Private/Protocol/Crypto.h | 431 +++++++++++++++
5 files changed, 1422 insertions(+)
diff --git a/CryptoPkg/CryptoPkg.dsc b/CryptoPkg/CryptoPkg.dsc
index a766851728..4f6cece6ee 100644
--- a/CryptoPkg/CryptoPkg.dsc
+++ b/CryptoPkg/CryptoPkg.dsc
@@ -169,6 +169,7 @@
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.TlsSet.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.TlsGet.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.Bn.Family | PCD_CRYPTO_SERVICE_ENABLE_FAMILY
+ gEfiCryptoPkgTokenSpaceGuid.PcdCryptoServiceFamilyEnable.Ec.Family | 0
!endif
!if $(CRYPTO_SERVICES) == MIN_PEI
diff --git a/CryptoPkg/Driver/Crypto.c b/CryptoPkg/Driver/Crypto.c
index 07150ad2f2..f7b9287218 100644
--- a/CryptoPkg/Driver/Crypto.c
+++ b/CryptoPkg/Driver/Crypto.c
@@ -5074,6 +5074,481 @@ CryptoServiceBigNumAddMod (
return CALL_BASECRYPTLIB (Bn.Services.AddMod, BigNumAddMod, (BnA, BnB, BnM, BnRes), FALSE);
}
+// =====================================================================================
+// Basic Elliptic Curve Primitives
+// =====================================================================================
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+CryptoServiceEcGroupInit (
+ IN UINTN CryptoNid
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.GroupInit, EcGroupInit, (CryptoNid), NULL);
+}
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient.
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.GroupGetCurve, EcGroupGetCurve, (EcGroup, BnPrime, BnA, BnB, BnCtx), FALSE);
+}
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.GroupGetOrder, EcGroupGetOrder, (EcGroup, BnOrder), FALSE);
+}
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+CryptoServiceEcGroupFree (
+ IN VOID *EcGroup
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Ec.Services.GroupFree, EcGroupFree, (EcGroup));
+}
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+CryptoServiceEcPointInit (
+ IN CONST VOID *EcGroup
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointInit, EcPointInit, (EcGroup), NULL);
+}
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+CryptoServiceEcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Ec.Services.PointDeInit, EcPointDeInit, (EcPoint, Clear));
+}
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointGetAffineCoordinates, EcPointGetAffineCoordinates, (EcGroup, EcPoint, BnX, BnY, BnCtx), FALSE);
+}
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointSetAffineCoordinates, EcPointSetAffineCoordinates, (EcGroup, EcPoint, BnX, BnY, BnCtx), FALSE);
+}
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointAdd, EcPointAdd, (EcGroup, EcPointResult, EcPointA, EcPointB, BnCtx), FALSE);
+}
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointMul, EcPointMul, (EcGroup, EcPointResult, EcPoint, BnPScalar, BnCtx), FALSE);
+}
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointInvert, EcPointInvert, (EcGroup, EcPoint, BnCtx), FALSE);
+}
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointIsOnCurve, EcPointIsOnCurve, (EcGroup, EcPoint, BnCtx), FALSE);
+}
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointIsAtInfinity, EcPointIsAtInfinity, (EcGroup, EcPoint), FALSE);
+}
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointEqual, EcPointEqual, (EcGroup, EcPointA, EcPointB, BnCtx), FALSE);
+}
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.PointSetCompressedCoordinates, EcPointSetCompressedCoordinates, (EcGroup, EcPoint, BnX, YBit, BnCtx), FALSE);
+}
+
+// =====================================================================================
+// Elliptic Curve Diffie Hellman Primitives
+// =====================================================================================
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+CryptoServiceEcNewByNid (
+ IN UINTN Nid
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.NewByNid, EcNewByNid, (Nid), NULL);
+}
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+CryptoServiceEcFree (
+ IN VOID *EcContext
+ )
+{
+ CALL_VOID_BASECRYPTLIB (Ec.Services.Free, EcFree, (EcContext));
+}
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.GenerateKey, EcGenerateKey, (EcContext, PublicKey, PublicKeySize), FALSE);
+}
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.GetPubKey, EcGetPubKey, (EcContext, PublicKey, PublicKeySize), FALSE);
+}
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+CryptoServiceEcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ )
+{
+ return CALL_BASECRYPTLIB (Ec.Services.DhComputeKey, EcDhComputeKey, (EcContext, PeerPublic, PeerPublicSize, CompressFlag ,Key, KeySize), FALSE);
+}
+
const EDKII_CRYPTO_PROTOCOL mEdkiiCrypto = {
/// Version
CryptoServiceGetCryptoVersion,
@@ -5306,4 +5781,25 @@ const EDKII_CRYPTO_PROTOCOL mEdkiiCrypto = {
CryptoServiceBigNumContextFree,
CryptoServiceBigNumSetUint,
CryptoServiceBigNumAddMod,
+ /// EC
+ CryptoServiceEcGroupInit,
+ CryptoServiceEcGroupGetCurve,
+ CryptoServiceEcGroupGetOrder,
+ CryptoServiceEcGroupFree,
+ CryptoServiceEcPointInit,
+ CryptoServiceEcPointDeInit,
+ CryptoServiceEcPointGetAffineCoordinates,
+ CryptoServiceEcPointSetAffineCoordinates,
+ CryptoServiceEcPointAdd,
+ CryptoServiceEcPointMul,
+ CryptoServiceEcPointInvert,
+ CryptoServiceEcPointIsOnCurve,
+ CryptoServiceEcPointIsAtInfinity,
+ CryptoServiceEcPointEqual,
+ CryptoServiceEcPointSetCompressedCoordinates,
+ CryptoServiceEcNewByNid,
+ CryptoServiceEcFree,
+ CryptoServiceEcGenerateKey,
+ CryptoServiceEcGetPubKey,
+ CryptoServiceEcDhComputeKey,
};
diff --git a/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h b/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
index 1b3c9d8f52..65ea7807dc 100644
--- a/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
+++ b/CryptoPkg/Include/Pcd/PcdCryptoServiceFamilyEnable.h
@@ -331,6 +331,31 @@ typedef struct {
} Services;
UINT32 Family;
} Bn;
+ union {
+ struct {
+ UINT8 GroupInit : 1;
+ UINT8 GroupGetCurve : 1;
+ UINT8 GroupGetOrder : 1;
+ UINT8 GroupFree : 1;
+ UINT8 PointInit : 1;
+ UINT8 PointDeInit : 1;
+ UINT8 PointGetAffineCoordinates : 1;
+ UINT8 PointSetAffineCoordinates : 1;
+ UINT8 PointAdd : 1;
+ UINT8 PointMul : 1;
+ UINT8 PointInvert : 1;
+ UINT8 PointIsOnCurve : 1;
+ UINT8 PointIsAtInfinity : 1;
+ UINT8 PointEqual : 1;
+ UINT8 PointSetCompressedCoordinates : 1;
+ UINT8 NewByNid : 1;
+ UINT8 Free : 1;
+ UINT8 GenerateKey : 1;
+ UINT8 GetPubKey : 1;
+ UINT8 DhComputeKey : 1;
+ } Services;
+ UINT32 Family;
+ } Ec;
} PCD_CRYPTO_SERVICE_FAMILY_ENABLE;
#endif
diff --git a/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c b/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
index c5d71b5269..3746c823d9 100644
--- a/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
+++ b/CryptoPkg/Library/BaseCryptLibOnProtocolPpi/CryptLib.c
@@ -4104,3 +4104,472 @@ BigNumAddMod (
{
CALL_CRYPTO_SERVICE (BigNumAddMod, (BnA, BnB, BnM, BnRes), FALSE);
}
+
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcGroupInit (
+ IN UINTN CryptoNid
+ )
+{
+ CALL_CRYPTO_SERVICE (EcGroupInit, (CryptoNid), NULL);
+}
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient.
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetCurve (
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcGroupGetCurve, (EcGroup, BnPrime, BnA, BnB, BnCtx), FALSE);
+}
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnOrder Group prime number.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcGroupGetOrder (
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ )
+{
+ CALL_CRYPTO_SERVICE (EcGroupGetOrder, (EcGroup, BnOrder), FALSE);
+}
+
+/**
+ Free previously allocated EC group object using EcGroupInit().
+
+ @param[in] EcGroup EC group object to free.
+**/
+VOID
+EFIAPI
+EcGroupFree (
+ IN VOID *EcGroup
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (EcGroupFree, (EcGroup));
+}
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit().
+
+ @retval EC Point object On success.
+ @retval NULL On failure.
+**/
+VOID *
+EFIAPI
+EcPointInit (
+ IN CONST VOID *EcGroup
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointInit, (EcGroup), NULL);
+}
+
+/**
+ Free previously allocated EC Point object using EcPointInit().
+
+ @param[in] EcPoint EC Point to free.
+ @param[in] Clear TRUE iff the memory should be cleared.
+**/
+VOID
+EFIAPI
+EcPointDeInit (
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (EcPointDeInit, (EcPoint, Clear));
+}
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[out] BnX X coordinate.
+ @param[out] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointGetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointGetAffineCoordinates, (EcGroup, EcPoint, BnX, BnY, BnCtx), FALSE);
+}
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point object.
+ @param[in] BnX X coordinate.
+ @param[in] BnY Y coordinate.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetAffineCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointSetAffineCoordinates, (EcGroup, EcPoint, BnX, BnY, BnCtx), FALSE);
+}
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point.
+ @param[in] EcPointB EC Point.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointAdd (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointAdd, (EcGroup, EcPointResult, EcPointA, EcPointB, BnCtx), FALSE);
+}
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar.
+
+ @param[in] EcGroup EC group object.
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point.
+ @param[in] BnPScalar P Scalar.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointMul (
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointMul, (EcGroup, EcPointResult, EcPoint, BnPScalar, BnCtx), FALSE);
+}
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object.
+ @param[in,out] EcPoint EC point to invert.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointInvert (
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointInvert, (EcGroup, EcPoint, BnCtx), FALSE);
+}
+
+/**
+ Check if the supplied point is on EC curve.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On curve.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsOnCurve (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointIsOnCurve, (EcGroup, EcPoint, BnCtx), FALSE);
+}
+
+/**
+ Check if the supplied point is at infinity.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC point to check.
+
+ @retval TRUE At infinity.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointIsAtInfinity (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointIsAtInfinity, (EcGroup, EcPoint), FALSE);
+}
+
+/**
+ Check if EC points are equal.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPointA EC point A.
+ @param[in] EcPointB EC point B.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE A == B.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointEqual (
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointEqual, (EcGroup, EcPointA, EcPointB, BnCtx), FALSE);
+}
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object.
+ @param[in] EcPoint EC Point.
+ @param[in] BnX X coordinate.
+ @param[in] YBit 0 or 1 to identify which Y value is used.
+ @param[in] BnCtx BN context, created with BigNumNewContext().
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+BOOLEAN
+EFIAPI
+EcPointSetCompressedCoordinates (
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ )
+{
+ CALL_CRYPTO_SERVICE (EcPointSetCompressedCoordinates, (EcGroup, EcPoint, BnX, YBit, BnCtx), FALSE);
+}
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+VOID *
+EFIAPI
+EcNewByNid (
+ IN UINTN Nid
+ )
+{
+ CALL_CRYPTO_SERVICE (EcNewByNid, (Nid), NULL);
+}
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+VOID
+EFIAPI
+EcFree (
+ IN VOID *EcContext
+ )
+{
+ CALL_VOID_CRYPTO_SERVICE (EcFree, (EcContext));
+}
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to the buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcGenerateKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ CALL_CRYPTO_SERVICE (EcGenerateKey, (EcContext, PublicKey, PublicKeySize), FALSE);
+}
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+BOOLEAN
+EFIAPI
+EcGetPubKey (
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ )
+{
+ CALL_CRYPTO_SERVICE (EcGetPubKey, (EcContext, PublicKey, PublicKeySize), FALSE);
+}
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+BOOLEAN
+EFIAPI
+EcDhComputeKey (
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ )
+{
+ CALL_CRYPTO_SERVICE (EcDhComputeKey, (EcContext, PeerPublic, PeerPublicSize, CompressFlag, Key, KeySize), FALSE);
+}
diff --git a/CryptoPkg/Private/Protocol/Crypto.h b/CryptoPkg/Private/Protocol/Crypto.h
index ec3cba8e93..84d9fbba32 100644
--- a/CryptoPkg/Private/Protocol/Crypto.h
+++ b/CryptoPkg/Private/Protocol/Crypto.h
@@ -3887,6 +3887,416 @@ BOOLEAN
OUT VOID *BnRes
);
+/**
+ Initialize new opaque EcGroup object. This object represents an EC curve and
+ and is used for calculation within this group. This object should be freed
+ using EcGroupFree() function.
+
+ @param[in] CryptoNid Identifying number for the ECC curve (Defined in
+ BaseCryptLib.h).
+
+ @retval EcGroup object On success
+ @retval NULL On failure
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_EC_GROUP_INIT)(
+ IN UINTN CryptoNid
+ );
+
+/**
+ Get EC curve parameters. While elliptic curve equation is Y^2 mod P = (X^3 + AX + B) Mod P.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object.
+ @param[out] BnPrime Group prime number.
+ @param[out] BnA A coefficient.
+ @param[out] BnB B coefficient.
+ @param[in] BnCtx BN context.
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_GROUP_GET_CURVE)(
+ IN CONST VOID *EcGroup,
+ OUT VOID *BnPrime,
+ OUT VOID *BnA,
+ OUT VOID *BnB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Get EC group order.
+ This function will set the provided Big Number object to the corresponding
+ value. The caller needs to make sure that the "out" BigNumber parameter
+ is properly initialized.
+
+ @param[in] EcGroup EC group object
+ @param[out] BnOrder Group prime number
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_GROUP_GET_ORDER)(
+ IN VOID *EcGroup,
+ OUT VOID *BnOrder
+ );
+
+/**
+ Free previously allocated EC group object using EcGroupInit()
+
+ @param[in] EcGroup EC group object to free
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_EC_GROUP_FREE)(
+ IN VOID *EcGroup
+ );
+
+/**
+ Initialize new opaque EC Point object. This object represents an EC point
+ within the given EC group (curve).
+
+ @param[in] EC Group, properly initialized using EcGroupInit()
+
+ @retval EC Point object On success
+ @retval NULL On failure
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_EC_POINT_INIT)(
+ IN CONST VOID *EcGroup
+ );
+
+/**
+ Free previously allocated EC Point object using EcPointInit()
+
+ @param[in] EcPoint EC Point to free
+ @param[in] Clear TRUE iff the memory should be cleared
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_EC_POINT_DE_INIT)(
+ IN VOID *EcPoint,
+ IN BOOLEAN Clear
+ );
+
+/**
+ Get EC point affine (x,y) coordinates.
+ This function will set the provided Big Number objects to the corresponding
+ values. The caller needs to make sure all the "out" BigNumber parameters
+ are properly initialized.
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPoint EC point object
+ @param[out] BnX X coordinate
+ @param[out] BnY Y coordinate
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_GET_AFFINE_COORDINATES)(
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ OUT VOID *BnX,
+ OUT VOID *BnY,
+ IN VOID *BnCtx
+ );
+
+/**
+ Set EC point affine (x,y) coordinates.
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPoint EC point object
+ @param[in] BnX X coordinate
+ @param[in] BnY Y coordinate
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_SET_AFFINE_COORDINATES)(
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN CONST VOID *BnY,
+ IN VOID *BnCtx
+ );
+
+/**
+ EC Point addition. EcPointResult = EcPointA + EcPointB
+
+ @param[in] EcGroup EC group object
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPointA EC Point
+ @param[in] EcPointB EC Point
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_ADD)(
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Variable EC point multiplication. EcPointResult = EcPoint * BnPScalar
+
+ @param[in] EcGroup EC group object
+ @param[out] EcPointResult EC point to hold the result. The point should
+ be properly initialized.
+ @param[in] EcPoint EC Point
+ @param[in] BnPScalar P Scalar
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_MUL)(
+ IN CONST VOID *EcGroup,
+ OUT VOID *EcPointResult,
+ IN CONST VOID *EcPoint,
+ IN CONST VOID *BnPScalar,
+ IN VOID *BnCtx
+ );
+
+/**
+ Calculate the inverse of the supplied EC point.
+
+ @param[in] EcGroup EC group object
+ @param[in,out] EcPoint EC point to invert
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_INVERT)(
+ IN CONST VOID *EcGroup,
+ IN OUT VOID *EcPoint,
+ IN VOID *BnCtx
+ );
+
+/**
+ Check if the supplied point is on EC curve
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPoint EC point to check
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On curve
+ @retval FALSE Otherwise
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_IS_ON_CURVE)(
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint,
+ IN VOID *BnCtx
+ );
+
+/**
+ Check if the supplied point is at infinity
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPoint EC point to check
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE At infinity
+ @retval FALSE Otherwise
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_IS_AT_INFINITY)(
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPoint
+ );
+
+/**
+ Check if EC points are equal
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPointA EC point A
+ @param[in] EcPointB EC point B
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE A == B
+ @retval FALSE Otherwise
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_EQUAL)(
+ IN CONST VOID *EcGroup,
+ IN CONST VOID *EcPointA,
+ IN CONST VOID *EcPointB,
+ IN VOID *BnCtx
+ );
+
+/**
+ Set EC point compressed coordinates. Points can be described in terms of
+ their compressed coordinates. For a point (x, y), for any given value for x
+ such that the point is on the curve there will only ever be two possible
+ values for y. Therefore, a point can be set using this function where BnX is
+ the x coordinate and YBit is a value 0 or 1 to identify which of the two
+ possible values for y should be used.
+
+ @param[in] EcGroup EC group object
+ @param[in] EcPoint EC Point
+ @param[in] BnX X coordinate
+ @param[in] YBit 0 or 1 to identify which Y value is used
+ @param[in] BnCtx BN context, created with BigNumNewContext()
+
+ @retval TRUE On success.
+ @retval FALSE Otherwise.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_POINT_SET_COMPRESSED_COORDINATES)(
+ IN CONST VOID *EcGroup,
+ IN VOID *EcPoint,
+ IN CONST VOID *BnX,
+ IN UINT8 YBit,
+ IN VOID *BnCtx
+ );
+
+/**
+ Allocates and Initializes one Elliptic Curve Context for subsequent use
+ with the NID.
+
+ @param[in] Nid cipher NID
+ @return Pointer to the Elliptic Curve Context that has been initialized.
+ If the allocations fails, EcNewByNid() returns NULL.
+**/
+typedef
+VOID *
+(EFIAPI *EDKII_CRYPTO_EC_NEW_BY_NID)(
+ IN UINTN Nid
+ );
+
+/**
+ Release the specified EC context.
+
+ @param[in] EcContext Pointer to the EC context to be released.
+**/
+typedef
+VOID
+(EFIAPI *EDKII_CRYPTO_EC_FREE)(
+ IN VOID *EcContext
+ );
+
+/**
+ Generates EC key and returns EC public key (X, Y), Please note, this function uses
+ pseudo random number generator. The caller must make sure RandomSeed()
+ function was properly called before.
+ The Ec context should be correctly initialized by EcNewByNid.
+ This function generates random secret, and computes the public key (X, Y), which is
+ returned via parameter Public, PublicSize.
+ X is the first half of Public with size being PublicSize / 2,
+ Y is the second half of Public with size being PublicSize / 2.
+ EC context is updated accordingly.
+ If the Public buffer is too small to hold the public X, Y, FALSE is returned and
+ PublicSize is set to the required buffer size to obtain the public X, Y.
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ If EcContext is NULL, then return FALSE.
+ If PublicSize is NULL, then return FALSE.
+ If PublicSize is large enough but Public is NULL, then return FALSE.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC public X,Y generation succeeded.
+ @retval FALSE EC public X,Y generation failed.
+ @retval FALSE PublicKeySize is not large enough.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_GENERATE_KEY)(
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ );
+
+/**
+ Gets the public key component from the established EC context.
+ The Ec context should be correctly initialized by EcNewByNid, and successfully
+ generate key pair from EcGenerateKey().
+ For P-256, the PublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to EC context being set.
+ @param[out] PublicKey Pointer to t buffer to receive generated public X,Y.
+ @param[in, out] PublicKeySize On input, the size of Public buffer in bytes.
+ On output, the size of data returned in Public buffer in bytes.
+ @retval TRUE EC key component was retrieved successfully.
+ @retval FALSE Invalid EC key component.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_GET_PUB_KEY)(
+ IN OUT VOID *EcContext,
+ OUT UINT8 *PublicKey,
+ IN OUT UINTN *PublicKeySize
+ );
+
+/**
+ Computes exchanged common key.
+ Given peer's public key (X, Y), this function computes the exchanged common key,
+ based on its own context including value of curve parameter and random secret.
+ X is the first half of PeerPublic with size being PeerPublicSize / 2,
+ Y is the second half of PeerPublic with size being PeerPublicSize / 2.
+ If EcContext is NULL, then return FALSE.
+ If PeerPublic is NULL, then return FALSE.
+ If PeerPublicSize is 0, then return FALSE.
+ If Key is NULL, then return FALSE.
+ If KeySize is not large enough, then return FALSE.
+ For P-256, the PeerPublicSize is 64. First 32-byte is X, Second 32-byte is Y.
+ For P-384, the PeerPublicSize is 96. First 48-byte is X, Second 48-byte is Y.
+ For P-521, the PeerPublicSize is 132. First 66-byte is X, Second 66-byte is Y.
+ @param[in, out] EcContext Pointer to the EC context.
+ @param[in] PeerPublic Pointer to the peer's public X,Y.
+ @param[in] PeerPublicSize Size of peer's public X,Y in bytes.
+ @param[in] CompressFlag Flag of PeerPublic is compressed or not.
+ @param[out] Key Pointer to the buffer to receive generated key.
+ @param[in, out] KeySize On input, the size of Key buffer in bytes.
+ On output, the size of data returned in Key buffer in bytes.
+ @retval TRUE EC exchanged key generation succeeded.
+ @retval FALSE EC exchanged key generation failed.
+ @retval FALSE KeySize is not large enough.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EDKII_CRYPTO_EC_DH_COMPUTE_KEY)(
+ IN OUT VOID *EcContext,
+ IN CONST UINT8 *PeerPublic,
+ IN UINTN PeerPublicSize,
+ IN CONST INT32 *CompressFlag,
+ OUT UINT8 *Key,
+ IN OUT UINTN *KeySize
+ );
+
///
/// EDK II Crypto Protocol
///
@@ -4102,6 +4512,27 @@ struct _EDKII_CRYPTO_PROTOCOL {
EDKII_CRYPTO_BIGNUM_CONTEXT_FREE BigNumContextFree;
EDKII_CRYPTO_BIGNUM_SET_UINT BigNumSetUint;
EDKII_CRYPTO_BIGNUM_ADD_MOD BigNumAddMod;
+ /// EC
+ EDKII_CRYPTO_EC_GROUP_INIT EcGroupInit;
+ EDKII_CRYPTO_EC_GROUP_GET_CURVE EcGroupGetCurve;
+ EDKII_CRYPTO_EC_GROUP_GET_ORDER EcGroupGetOrder;
+ EDKII_CRYPTO_EC_GROUP_FREE EcGroupFree;
+ EDKII_CRYPTO_EC_POINT_INIT EcPointInit;
+ EDKII_CRYPTO_EC_POINT_DE_INIT EcPointDeInit;
+ EDKII_CRYPTO_EC_POINT_GET_AFFINE_COORDINATES EcPointGetAffineCoordinates;
+ EDKII_CRYPTO_EC_POINT_SET_AFFINE_COORDINATES EcPointSetAffineCoordinates;
+ EDKII_CRYPTO_EC_POINT_ADD EcPointAdd;
+ EDKII_CRYPTO_EC_POINT_MUL EcPointMul;
+ EDKII_CRYPTO_EC_POINT_INVERT EcPointInvert;
+ EDKII_CRYPTO_EC_POINT_IS_ON_CURVE EcPointIsOnCurve;
+ EDKII_CRYPTO_EC_POINT_IS_AT_INFINITY EcPointIsAtInfinity;
+ EDKII_CRYPTO_EC_POINT_EQUAL EcPointEqual;
+ EDKII_CRYPTO_EC_POINT_SET_COMPRESSED_COORDINATES EcPointSetCompressedCoordinates;
+ EDKII_CRYPTO_EC_NEW_BY_NID EcNewByNid;
+ EDKII_CRYPTO_EC_FREE EcFree;
+ EDKII_CRYPTO_EC_GENERATE_KEY EcGenerateKey;
+ EDKII_CRYPTO_EC_GET_PUB_KEY EcGetPubKey;
+ EDKII_CRYPTO_EC_DH_COMPUTE_KEY EcDhComputeKey;
};
extern GUID gEdkiiCryptoProtocolGuid;
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 5/7] CryptoPkg/Test: Add unit test for CryptoBn
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
` (3 preceding siblings ...)
2022-09-07 8:29 ` [PATCH 4/7] CryptoPkg: Add EC APIs to DXE and protocol yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 6/7] CryptoPkg/Test: Add unit test for CryptoEc yi1 li
` (2 subsequent siblings)
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
Add unit test for CryptoBn.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
.../BaseCryptLib/UnitTestHostBaseCryptLib.inf | 1 +
.../BaseCryptLib/BaseCryptLibUnitTests.c | 1 +
.../UnitTest/Library/BaseCryptLib/BnTests.c | 257 ++++++++++++++++++
.../Library/BaseCryptLib/TestBaseCryptLib.h | 3 +
.../BaseCryptLib/TestBaseCryptLibHost.inf | 1 +
.../BaseCryptLib/TestBaseCryptLibShell.inf | 1 +
6 files changed, 264 insertions(+)
create mode 100644 CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
diff --git a/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
index 11ff1c6931..cf8810e598 100644
--- a/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
@@ -46,6 +46,7 @@
Pem/CryptPem.c
Pk/CryptRsaPss.c
Pk/CryptRsaPssSign.c
+ Bn/CryptBn.c
SysCall/UnitTestHostCrtWrapper.c
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
index 3c57aead1e..792006a194 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
@@ -25,6 +25,7 @@ SUITE_DESC mSuiteDesc[] = {
{ "DH verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mDhTestNum, mDhTest },
{ "PRNG verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mPrngTestNum, mPrngTest },
{ "OAEP encrypt verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mOaepTestNum, mOaepTest },
+ { "Bn verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mBnTestNum, mBnTest },
};
EFI_STATUS
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
new file mode 100644
index 0000000000..df91752c9c
--- /dev/null
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
@@ -0,0 +1,257 @@
+/** @file
+ Application for BigNumber Primitives Validation.
+
+Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include "TestBaseCryptLib.h"
+
+//
+// Debug data
+//
+#define MAX_TEST_DATA_SIZE 512
+#define BYTES_OF_OPERATION_A 60
+#define BITS_OF_OPERATION_A 480 //(8 * 60)
+
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationA[] = {
+ 0x00, 0x00, 0x00, 0x00, 0x93, 0x61, 0x7a, 0xba, 0xcc, 0x41, 0x73, 0x49, 0xae, 0x20, 0x41, 0x31,
+ 0x12, 0xe6, 0xfa, 0x4e, 0x89, 0xa9, 0x7e, 0xa2, 0x0a, 0x9e, 0xee, 0xe6, 0x4b, 0x55, 0xd3, 0x9a,
+ 0x21, 0x92, 0x99, 0x2a, 0x27, 0x4f, 0xc1, 0xa8, 0x36, 0xba, 0x3c, 0x23, 0xa3, 0xfe, 0xeb, 0xbd,
+ 0x45, 0x4d, 0x44, 0x23, 0x64, 0x3c, 0xe8, 0x0e, 0x2a, 0x9a, 0xc9, 0x4f, 0xa5, 0x4c, 0xa4, 0x9f
+};
+
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationB[] = {
+ 0xb0, 0x03, 0x61, 0xa3, 0x96, 0x17, 0x7a, 0x9c, 0xb4, 0x10, 0xff, 0x61, 0xf2, 0x00, 0x15, 0xad,
+ 0xcb, 0x00, 0x75, 0x3f, 0x45, 0xa3, 0x5e, 0x8b, 0xb5, 0xa0, 0x3d, 0x69, 0x9a, 0xc6, 0x50, 0x07,
+ 0x27, 0x2c, 0x32, 0xab, 0x0e, 0xde, 0xd1, 0x63, 0x1a, 0x8b, 0x60, 0x5a, 0x43, 0xff, 0x5b, 0xed,
+ 0x80, 0x86, 0x07, 0x2b, 0xa1, 0xe7, 0xcc, 0x23, 0x58, 0xba, 0xec, 0xa1, 0x34, 0xc8, 0x25, 0xa7
+};
+
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationC[] = {
+ 0x27, 0x2c, 0x32, 0xab, 0x0e, 0xde, 0xd1, 0x63, 0x1a, 0x8b, 0x60, 0x5a, 0x43, 0xff, 0x5b, 0xed
+};
+
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationExp[] = {
+ 0x27, 0x2c, 0x32, 0xab, 0x0e, 0xde, 0xd1, 0x63
+};
+
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationMod[] = {
+ 0x48, 0xbe, 0xcb, 0xd5, 0x36, 0x2e, 0x93, 0x0b, 0x51, 0x45, 0x9c, 0x7d, 0xe7, 0xfe, 0x47, 0xaa,
+ 0xc5, 0xd3, 0x4b, 0x4f, 0x06, 0x24, 0xb4, 0x31, 0x83, 0x55, 0xb5, 0xf0, 0xda, 0x14, 0xca, 0x46
+};
+
+// BnOperationA + BnOperationB
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultSum[] = {
+ 0xb0, 0x03, 0x61, 0xa4, 0x29, 0x78, 0xf5, 0x57, 0x80, 0x52, 0x72, 0xab, 0xa0, 0x20, 0x56, 0xde,
+ 0xdd, 0xe7, 0x6f, 0x8d, 0xcf, 0x4c, 0xdd, 0x2d, 0xc0, 0x3f, 0x2c, 0x4f, 0xe6, 0x1c, 0x23, 0xa1,
+ 0x48, 0xbe, 0xcb, 0xd5, 0x36, 0x2e, 0x93, 0x0b, 0x51, 0x45, 0x9c, 0x7d, 0xe7, 0xfe, 0x47, 0xaa,
+ 0xc5, 0xd3, 0x4b, 0x4f, 0x06, 0x24, 0xb4, 0x31, 0x83, 0x55, 0xb5, 0xf0, 0xda, 0x14, 0xca, 0x46
+};
+
+// (BnOperationA + BnOperationC) % BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultSumMod[] = {
+ 0x16, 0x0a, 0xcf, 0x78, 0x20, 0xac, 0x31, 0x53, 0xd9, 0x0f, 0x22, 0xfc, 0x08, 0x8d, 0xde, 0x0d,
+ 0x29, 0xf4, 0x07, 0xdd, 0xfa, 0xf5, 0x61, 0xd4, 0x1a, 0xe5, 0xa1, 0xef, 0x4a, 0x37, 0xfe, 0xec
+};
+
+// (BnOperationA * BnOperationC) % BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultMulMod[] = {
+ 0x01, 0xDB, 0xD2, 0x82, 0xC9, 0x24, 0x66, 0x2A, 0x96, 0x05, 0x11, 0xF2, 0x31, 0xF0, 0xCB, 0x28,
+ 0xBA, 0x5C, 0xBE, 0x7D, 0xEE, 0x37, 0x25, 0xB1, 0x24, 0x7E, 0x15, 0xAB, 0xCD, 0x86, 0x8E, 0x39
+};
+
+// BnOperationA / BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultDiv[] = {
+ 0x02, 0x06, 0xA6, 0xDC, 0x2E, 0x97, 0x05, 0xEA, 0xCD, 0xF7, 0xAB, 0xCD, 0xE5, 0x9C, 0x33, 0x03,
+ 0xCE, 0x3D, 0x7E, 0x63, 0x23, 0xB2, 0xEC, 0xED, 0x96, 0x9D, 0xC9, 0xBB, 0x78
+};
+
+// BnOperationA % BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultMod[] = {
+ 0x06, 0x2A, 0x8D, 0x06, 0x9D, 0x14, 0x53, 0x3B, 0x05, 0xD9, 0x86, 0x00, 0xA5, 0xB9, 0x05, 0x7F,
+ 0xC1, 0x82, 0xEC, 0x23, 0x44, 0x23, 0xC8, 0xA2, 0x42, 0xB3, 0x43, 0xB8, 0x7C, 0xD6, 0xB1, 0xCF
+};
+
+// BnOperationA % BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultInverseMod[] = {
+ 0x3a, 0xeb, 0xc5, 0x98, 0x9c, 0x22, 0xd6, 0x76, 0x7d, 0x1c, 0xc6, 0xd6, 0xbb, 0x1b, 0xed, 0xfd,
+ 0x0f, 0x34, 0xbf, 0xe0, 0x2b, 0x4a, 0x26, 0xc3, 0xc0, 0xd9, 0x57, 0xc7, 0x11, 0xc0, 0xd6, 0x35
+};
+
+// BnOperationA % BnOperationMod
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultExpMod[] = {
+ 0x39, 0xf8, 0x74, 0xa0, 0xe8, 0x02, 0x8b, 0xf2, 0x22, 0x62, 0x82, 0x4c, 0xe0, 0xed, 0x63, 0x48,
+ 0xb9, 0xa2, 0xaa, 0xbc, 0xba, 0xb1, 0xd3, 0x6a, 0x02, 0xfd, 0xf3, 0x0e, 0x3a, 0x19, 0x39, 0x37
+};
+
+// BnOperationA >> 128
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultRShift[] = {
+ 0x93, 0x61, 0x7a, 0xba, 0xcc, 0x41, 0x73, 0x49, 0xae, 0x20, 0x41, 0x31,
+ 0x12, 0xe6, 0xfa, 0x4e, 0x89, 0xa9, 0x7e, 0xa2, 0x0a, 0x9e, 0xee, 0xe6, 0x4b, 0x55, 0xd3, 0x9a,
+ 0x21, 0x92, 0x99, 0x2a, 0x27, 0x4f, 0xc1, 0xa8, 0x36, 0xba, 0x3c, 0x23, 0xa3, 0xfe, 0xeb, 0xbd
+};
+
+// 0x12345678
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultUIntSet[] = {0x12, 0x34, 0x56, 0x78};
+
+typedef struct {
+ VOID *BnA;
+ VOID *BnB;
+ VOID *BnC;
+ VOID *BnD;
+ VOID *BnCTX;
+} BN_TEST_CONTEXT;
+
+GLOBAL_REMOVE_IF_UNREFERENCED STATIC BN_TEST_CONTEXT mBnContext = {NULL, NULL, NULL, NULL, NULL};
+
+//
+// Debug function
+//
+STATIC
+BOOLEAN
+EqualBn2Bn (
+ CONST VOID *Expected, CONST VOID *Actual
+ )
+{
+ if (BigNumCmp(Expected, Actual) == 0)
+ return TRUE;
+ return FALSE;
+}
+
+STATIC
+BOOLEAN
+EqualBn2Bin (
+ CONST VOID *Bn, CONST UINT8 *Buffer, CONST UINTN BufferSize
+ )
+{
+ UINTN BnTestBufferSize;
+ UINT8 BnTestBuffer[MAX_TEST_DATA_SIZE];
+
+ BnTestBufferSize = BigNumToBin (Bn, BnTestBuffer);
+ if (BnTestBufferSize == BufferSize) {
+ if (CompareMem (Buffer, BnTestBuffer, BnTestBufferSize) == 0) {
+ return TRUE;
+ }
+ }
+ return FALSE;
+}
+
+UNIT_TEST_STATUS
+EFIAPI
+TestVerifyBnPreReq (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ BN_TEST_CONTEXT *BnContext;
+
+ BnContext = Context;
+ BnContext->BnCTX = BigNumNewContext();
+ BnContext->BnA = BigNumInit();
+ BnContext->BnB = BigNumInit();
+ BnContext->BnC = BigNumInit();
+ BnContext->BnD = BigNumInit();
+ if (BnContext->BnCTX == NULL
+ || BnContext->BnA == NULL
+ || BnContext->BnB == NULL
+ || BnContext->BnC == NULL
+ || BnContext->BnD == NULL
+ ) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+ return UNIT_TEST_PASSED;
+}
+
+VOID
+EFIAPI
+TestVerifyBnCleanUp (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ BN_TEST_CONTEXT *BnContext;
+
+ BnContext = Context;
+ BigNumContextFree (BnContext->BnCTX);
+ BigNumFree (BnContext->BnA, TRUE);
+ BigNumFree (BnContext->BnB, TRUE);
+ BigNumFree (BnContext->BnC, TRUE);
+ BigNumFree (BnContext->BnD, TRUE);
+}
+
+UNIT_TEST_STATUS
+EFIAPI
+TestVerifyBn (
+ IN UNIT_TEST_CONTEXT Context
+ )
+{
+ BN_TEST_CONTEXT *BnContext;
+ UINTN Num;
+ CONST VOID *BnOne;
+
+ BnContext = Context;
+
+ // Calculation tests
+ BnContext->BnA = BigNumFromBin (BnOperationA, sizeof (BnOperationA));
+ BnContext->BnB = BigNumFromBin (BnOperationB, sizeof (BnOperationB));
+ //C=A+B
+ BigNumAdd (BnContext->BnA, BnContext->BnB, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultSum, sizeof (BnResultSum)));
+ //D=C-A=B
+ BigNumSub (BnContext->BnC, BnContext->BnA, BnContext->BnD);
+ UT_ASSERT_TRUE (EqualBn2Bn (BnContext->BnB, BnContext->BnD));
+ //C=(A+B)%D
+ BnContext->BnD = BigNumFromBin (BnOperationMod, sizeof (BnOperationMod));
+ BigNumAddMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultSumMod, sizeof (BnResultSumMod)));
+ //C=(A*B)%D
+ BigNumMulMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultMulMod, sizeof (BnResultMulMod)));
+ //C=A/D
+ BigNumDiv (BnContext->BnA, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultDiv, sizeof (BnResultDiv)));
+ //C=A%D
+ BigNumMod (BnContext->BnA, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultMod, sizeof (BnResultMod)));
+ //1=(A*C)%D
+ BigNumInverseMod (BnContext->BnA, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultInverseMod, sizeof (BnResultInverseMod)));
+ //C=(A^B)%D
+ BnContext->BnB = BigNumFromBin (BnOperationExp, sizeof (BnOperationExp));
+ BigNumExpMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultExpMod, sizeof (BnResultExpMod)));
+ //C=A>>128
+ BigNumRShift (BnContext->BnA, 128, BnContext->BnC);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultRShift, sizeof (BnResultRShift)));
+ //C=0x12345678
+ BigNumSetUint (BnContext->BnC, 0x12345678);
+ UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultUIntSet, sizeof (BnResultUIntSet)));
+ //Bn compare
+ UT_ASSERT_TRUE (BigNumIsWord (BnContext->BnC, 0x12345678));
+ UT_ASSERT_FALSE (BigNumIsWord (BnContext->BnC, 0x12345600));
+ UT_ASSERT_FALSE (BigNumIsOdd (BnContext->BnC));
+ UT_ASSERT_TRUE (BigNumIsOdd (BnContext->BnA));
+
+ //Other tests
+ BigNumConstTime (BnContext->BnA);
+ Num = BigNumBytes (BnContext->BnA);
+ UT_ASSERT_EQUAL (Num, BYTES_OF_OPERATION_A);
+ Num = BigNumBits (BnContext->BnA);
+ UT_ASSERT_EQUAL (Num, BITS_OF_OPERATION_A);
+ BnOne = BigNumValueOne();
+ if (BnOne == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+ UT_ASSERT_TRUE (BigNumIsWord (BnOne, 0x1));
+
+ return UNIT_TEST_PASSED;
+}
+
+TEST_DESC mBnTest[] = {
+ //
+ // -----Description----------------Class---------------------Function-----------Pre----------------Post---------Context
+ //
+ { "TestVerifyBn()", "CryptoPkg.BaseCryptLib.BigNumber", TestVerifyBn, TestVerifyBnPreReq, TestVerifyBnCleanUp, &mBnContext },
+};
+
+UINTN mBnTestNum = ARRAY_SIZE(mBnTest);
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
index a6b3482742..b8f0fdfd89 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
@@ -86,6 +86,9 @@ extern TEST_DESC mOaepTest[];
extern UINTN mRsaPssTestNum;
extern TEST_DESC mRsaPssTest[];
+extern UINTN mBnTestNum;
+extern TEST_DESC mBnTest[];
+
/** Creates a framework you can use */
EFI_STATUS
EFIAPI
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
index 399db596c2..1301345a13 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
@@ -37,6 +37,7 @@
OaepEncryptTests.c
RsaPssTests.c
ParallelhashTests.c
+ BnTests.c
[Packages]
MdePkg/MdePkg.dec
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
index ca789aa6ad..9a41dbc317 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
@@ -36,6 +36,7 @@
Pkcs7EkuTests.c
OaepEncryptTests.c
RsaPssTests.c
+ BnTests.c
[Packages]
MdePkg/MdePkg.dec
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 6/7] CryptoPkg/Test: Add unit test for CryptoEc
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
` (4 preceding siblings ...)
2022-09-07 8:29 ` [PATCH 5/7] CryptoPkg/Test: Add unit test for CryptoBn yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-07 8:29 ` [PATCH 7/7] CryptoPkg: Run uncrustify tools on EC and BN change yi1 li
2022-09-20 16:01 ` [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib Yao, Jiewen
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
Add unit test for CryptoEc.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
.../BaseCryptLib/UnitTestHostBaseCryptLib.inf | 2 +
CryptoPkg/Test/CryptoPkgHostUnitTest.dsc | 3 +
.../BaseCryptLib/BaseCryptLibUnitTests.c | 1 +
.../UnitTest/Library/BaseCryptLib/EcTests.c | 289 ++++++++++++++++++
.../Library/BaseCryptLib/TestBaseCryptLib.h | 2 +
.../BaseCryptLib/TestBaseCryptLibHost.inf | 1 +
.../BaseCryptLib/TestBaseCryptLibShell.inf | 1 +
7 files changed, 299 insertions(+)
create mode 100644 CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
diff --git a/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf b/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
index cf8810e598..33df93c73c 100644
--- a/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
+++ b/CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
@@ -47,6 +47,8 @@
Pk/CryptRsaPss.c
Pk/CryptRsaPssSign.c
Bn/CryptBn.c
+ Pk/CryptEcNull.c |*|*|*|!gEfiCryptoPkgTokenSpaceGuid.PcdOpensslEcEnabled
+ Pk/CryptEc.c |*|*|*|gEfiCryptoPkgTokenSpaceGuid.PcdOpensslEcEnabled
SysCall/UnitTestHostCrtWrapper.c
diff --git a/CryptoPkg/Test/CryptoPkgHostUnitTest.dsc b/CryptoPkg/Test/CryptoPkgHostUnitTest.dsc
index 16478f4a57..b6e1a66198 100644
--- a/CryptoPkg/Test/CryptoPkgHostUnitTest.dsc
+++ b/CryptoPkg/Test/CryptoPkgHostUnitTest.dsc
@@ -19,6 +19,9 @@
!include UnitTestFrameworkPkg/UnitTestFrameworkPkgHost.dsc.inc
+[PcdsFixedAtBuild]
+ gEfiCryptoPkgTokenSpaceGuid.PcdOpensslEcEnabled|TRUE
+
[LibraryClasses]
OpensslLib|CryptoPkg/Library/OpensslLib/OpensslLib.inf
BaseCryptLib|CryptoPkg/Library/BaseCryptLib/UnitTestHostBaseCryptLib.inf
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
index 792006a194..359921fd5f 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BaseCryptLibUnitTests.c
@@ -26,6 +26,7 @@ SUITE_DESC mSuiteDesc[] = {
{ "PRNG verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mPrngTestNum, mPrngTest },
{ "OAEP encrypt verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mOaepTestNum, mOaepTest },
{ "Bn verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mBnTestNum, mBnTest },
+ { "EC verify tests", "CryptoPkg.BaseCryptLib", NULL, NULL, &mEcTestNum, mEcTest },
};
EFI_STATUS
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
new file mode 100644
index 0000000000..8008b1dc78
--- /dev/null
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
@@ -0,0 +1,289 @@
+/** @file
+ Application for Diffie-Hellman Primitives Validation.
+
+Copyright (c) 2022, Intel Corporation. All rights reserved.<BR>
+SPDX-License-Identifier: BSD-2-Clause-Patent
+
+**/
+
+#include "TestBaseCryptLib.h"
+
+#define EC_CURVE_NUM_SUPPORTED 3
+UINTN EcCurveList[EC_CURVE_NUM_SUPPORTED] = {CRYPTO_NID_SECP256R1, CRYPTO_NID_SECP384R1, CRYPTO_NID_SECP521R1};
+UINTN EcKeyHalfSize[EC_CURVE_NUM_SUPPORTED] = {32, 48, 66};
+
+struct Generator
+{
+ UINT8 X[66];
+ UINT8 Y[66];
+};
+// Generator points of all ec curve
+struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
+{
+ //CRYPTO_NID_SECP256R1
+ {
+ { 0x6B, 0x17, 0xD1, 0xF2, 0xE1, 0x2C, 0x42, 0x47, 0xF8, 0xBC, 0xE6, 0xE5,
+ 0x63, 0xA4, 0x40, 0xF2, 0x77, 0x03, 0x7D, 0x81, 0x2D, 0xEB, 0x33, 0xA0,
+ 0xF4, 0xA1, 0x39, 0x45, 0xD8, 0x98, 0xC2, 0x96 },
+
+ { 0x4f, 0xe3, 0x42, 0xe2, 0xfe, 0x1a, 0x7f, 0x9b, 0x8e, 0xe7, 0xeb, 0x4a,
+ 0x7c, 0x0f, 0x9e, 0x16, 0x2b, 0xce, 0x33, 0x57, 0x6b, 0x31, 0x5e, 0xce,
+ 0xcb, 0xb6, 0x40, 0x68, 0x37, 0xbf, 0x51, 0xf5 }
+ },
+ //CRYPTO_NID_SECP384R1
+ {
+ { 0xAA, 0x87, 0xCA, 0x22, 0xBE, 0x8B, 0x05, 0x37, 0x8E, 0xB1, 0xC7, 0x1E,
+ 0xF3, 0x20, 0xAD, 0x74, 0x6E, 0x1D, 0x3B, 0x62, 0x8B, 0xA7, 0x9B, 0x98,
+ 0x59, 0xF7, 0x41, 0xE0, 0x82, 0x54, 0x2A, 0x38, 0x55, 0x02, 0xF2, 0x5D,
+ 0xBF, 0x55, 0x29, 0x6C, 0x3A, 0x54, 0x5E, 0x38, 0x72, 0x76, 0x0A, 0xB7 },
+
+ { 0x36, 0x17, 0xde, 0x4a, 0x96, 0x26, 0x2c, 0x6f, 0x5d, 0x9e, 0x98, 0xbf,
+ 0x92, 0x92, 0xdc, 0x29, 0xf8, 0xf4, 0x1d, 0xbd, 0x28, 0x9a, 0x14, 0x7c,
+ 0xe9, 0xda, 0x31, 0x13, 0xb5, 0xf0, 0xb8, 0xc0, 0x0a, 0x60, 0xb1, 0xce,
+ 0x1d, 0x7e, 0x81, 0x9d, 0x7a, 0x43, 0x1d, 0x7c, 0x90, 0xea, 0x0e, 0x5f }
+ },
+ //CRYPTO_NID_SECP521R1
+ {
+ { 0x00, 0xC6, 0x85, 0x8E, 0x06, 0xB7, 0x04, 0x04, 0xE9, 0xCD, 0x9E, 0x3E,
+ 0xCB, 0x66, 0x23, 0x95, 0xB4, 0x42, 0x9C, 0x64, 0x81, 0x39, 0x05, 0x3F,
+ 0xB5, 0x21, 0xF8, 0x28, 0xAF, 0x60, 0x6B, 0x4D, 0x3D, 0xBA, 0xA1, 0x4B,
+ 0x5E, 0x77, 0xEF, 0xE7, 0x59, 0x28, 0xFE, 0x1D, 0xC1, 0x27, 0xA2, 0xFF,
+ 0xA8, 0xDE, 0x33, 0x48, 0xB3, 0xC1, 0x85, 0x6A, 0x42, 0x9B, 0xF9, 0x7E,
+ 0x7E, 0x31, 0xC2, 0xE5, 0xBD, 0x66 },
+
+ { 0x01, 0x18, 0x39, 0x29, 0x6a, 0x78, 0x9a, 0x3b, 0xc0, 0x04, 0x5c, 0x8a,
+ 0x5f, 0xb4, 0x2c, 0x7d, 0x1b, 0xd9, 0x98, 0xf5, 0x44, 0x49, 0x57, 0x9b,
+ 0x44, 0x68, 0x17, 0xaf, 0xbd, 0x17, 0x27, 0x3e, 0x66, 0x2c, 0x97, 0xee,
+ 0x72, 0x99, 0x5e, 0xf4, 0x26, 0x40, 0xc5, 0x50, 0xb9, 0x01, 0x3f, 0xad,
+ 0x07, 0x61, 0x35, 0x3c, 0x70, 0x86, 0xa2, 0x72, 0xc2, 0x40, 0x88, 0xbe,
+ 0x94, 0x76, 0x9f, 0xd1, 0x66, 0x50 }
+ }
+};
+
+VOID *Ec1 ;
+VOID *Ec2 ;
+VOID *Group ;
+VOID *Point1 ;
+VOID *Point2 ;
+VOID *PointRes;
+VOID *BnX ;
+VOID *BnY ;
+VOID *BnP ;
+VOID *BnOrder ;
+
+UNIT_TEST_STATUS
+EFIAPI
+TestVerifyEcPreReq (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ Ec1 = NULL;
+ Ec2 = NULL;
+ Group = NULL;
+ Point1 = NULL;
+ Point2 = NULL;
+ PointRes = NULL;
+ BnX = NULL;
+ BnY = NULL;
+ BnP = BigNumInit ();
+ BnOrder = BigNumInit ();
+ if (BnP == NULL || BnOrder == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+ return UNIT_TEST_PASSED;
+}
+
+VOID
+EFIAPI
+TestVerifyEcCleanUp (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ BigNumFree (BnX, TRUE);
+ BigNumFree (BnY, TRUE);
+ BigNumFree (BnP, TRUE);
+ BigNumFree (BnOrder, TRUE);
+ EcGroupFree (Group);
+ EcPointDeInit (Point1, TRUE);
+ EcPointDeInit (Point2, TRUE);
+ EcPointDeInit (PointRes, TRUE);
+ EcFree (Ec1);
+ EcFree (Ec2);
+}
+
+UNIT_TEST_STATUS
+EFIAPI
+TestVerifyEcBasic (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ UINTN CurveCount;
+ BOOLEAN Status;
+
+ //
+ // Initialize BigNumbers
+ //
+ for (CurveCount = 0; CurveCount < EC_CURVE_NUM_SUPPORTED; CurveCount++) {
+ //
+ // Basic EC functions unit test
+ //
+ Group = EcGroupInit (EcCurveList[CurveCount]);
+ if (Group == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+
+ Point1 = EcPointInit (Group);
+ Point2 = EcPointInit (Group);
+ PointRes = EcPointInit (Group);
+ BnX = BigNumFromBin (EcCurveGenerator[CurveCount].X, EcKeyHalfSize[CurveCount]);
+ BnY = BigNumFromBin (EcCurveGenerator[CurveCount].Y, EcKeyHalfSize[CurveCount]);
+ if (Point1 == NULL || Point2 == NULL || PointRes == NULL || BnX == NULL || BnY == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+
+ Status = EcGroupGetCurve (Group, BnP, NULL, NULL, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcGroupGetOrder (Group, BnOrder);
+ UT_ASSERT_TRUE (Status);
+
+ //Point G should on curve
+ Status = EcPointSetAffineCoordinates (Group, Point1, BnX, BnY, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointSetAffineCoordinates (Group, Point2, BnX, BnY, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointEqual (Group, Point1, Point2, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointIsOnCurve (Group, Point1, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointIsAtInfinity (Group, Point1);
+ UT_ASSERT_FALSE (Status);
+
+ //Point 2G should on curve
+ Status = EcPointAdd (Group, PointRes, Point1, Point1, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointIsOnCurve (Group, PointRes, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ //Point Order * G should at infinity
+ Status = EcPointMul (Group, PointRes, Point1, BnOrder, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointIsAtInfinity (Group, PointRes);
+ UT_ASSERT_TRUE (Status);
+
+ //-(-G) == G
+ Status = EcPointInvert (Group, Point2, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointEqual (Group, Point2, Point1, NULL);
+ UT_ASSERT_FALSE (Status);
+
+ Status = EcPointInvert (Group, Point2, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointEqual (Group, Point2, Point1, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ //Compress point test
+ Status = EcPointSetCompressedCoordinates (Group, Point1, BnX, 0, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointSetCompressedCoordinates (Group, Point2, BnX, 1, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointEqual (Group, Point2, Point1, NULL);
+ UT_ASSERT_FALSE (Status);
+
+ Status = EcPointInvert (Group, Point2, NULL);
+ UT_ASSERT_TRUE (Status);
+
+ Status = EcPointEqual (Group, Point2, Point1, NULL);
+ UT_ASSERT_TRUE (Status);
+ }
+
+ return UNIT_TEST_PASSED;
+}
+
+UNIT_TEST_STATUS
+EFIAPI
+TestVerifyEcDh (
+ UNIT_TEST_CONTEXT Context
+ )
+{
+ UINT8 Public1[66 * 2];
+ UINTN Public1Length;
+ UINT8 Public2[66 * 2];
+ UINTN Public2Length;
+ UINT8 Key1[66];
+ UINTN Key1Length;
+ UINT8 Key2[66];
+ UINTN Key2Length;
+ UINTN CurveCount;
+ BOOLEAN Status;
+
+ for (CurveCount = 0; CurveCount < EC_CURVE_NUM_SUPPORTED; CurveCount++) {
+ //
+ // Initial key length
+ //
+ Public1Length = sizeof (Public1);
+ Public2Length = sizeof (Public2);
+ Key1Length = sizeof (Key1);
+ Key2Length = sizeof (Key2);
+ //
+ // ECDH functions unit test
+ //
+ Ec1 = EcNewByNid (EcCurveList[CurveCount]);
+ if (Ec1 == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+
+ Ec2 = EcNewByNid (EcCurveList[CurveCount]);
+ if (Ec2 == NULL) {
+ return UNIT_TEST_ERROR_TEST_FAILED;
+ }
+
+ Status = EcGenerateKey (Ec1, Public1, &Public1Length);
+ UT_ASSERT_TRUE (Status);
+ UT_ASSERT_EQUAL (Public1Length, EcKeyHalfSize[CurveCount] * 2);
+
+ Status = EcGenerateKey (Ec2, Public2, &Public2Length);
+ UT_ASSERT_TRUE (Status);
+ UT_ASSERT_EQUAL (Public2Length, EcKeyHalfSize[CurveCount] * 2);
+
+ Status = EcDhComputeKey (Ec1, Public2, Public2Length, NULL, Key1, &Key1Length);
+ UT_ASSERT_TRUE (Status);
+ UT_ASSERT_EQUAL (Key1Length, EcKeyHalfSize[CurveCount]);
+
+ Status = EcDhComputeKey (Ec2, Public1, Public1Length, NULL, Key2, &Key2Length);
+ UT_ASSERT_TRUE (Status);
+ UT_ASSERT_EQUAL (Key2Length, EcKeyHalfSize[CurveCount]);
+
+ UT_ASSERT_EQUAL (Key1Length, Key2Length);
+ UT_ASSERT_MEM_EQUAL (Key1, Key2, Key1Length);
+
+ Status = EcGetPubKey (Ec1, Public2, &Public2Length);
+ UT_ASSERT_TRUE (Status);
+ UT_ASSERT_EQUAL (Public2Length, EcKeyHalfSize[CurveCount] * 2);
+
+ UT_ASSERT_EQUAL (Public1Length, Public2Length);
+ UT_ASSERT_MEM_EQUAL (Public1, Public2, Public1Length);
+ }
+
+ return UNIT_TEST_PASSED;
+}
+
+TEST_DESC mEcTest[] = {
+ //
+ // -----Description-----------------Class------------------Function----Pre----Post----Context
+ //
+ { "TestVerifyEcBasic()", "CryptoPkg.BaseCryptLib.Ec", TestVerifyEcBasic, TestVerifyEcPreReq, TestVerifyEcCleanUp, NULL },
+ { "TestVerifyEcDh()", "CryptoPkg.BaseCryptLib.Ec", TestVerifyEcDh, TestVerifyEcPreReq, TestVerifyEcCleanUp, NULL },
+};
+
+UINTN mEcTestNum = ARRAY_SIZE (mEcTest);
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
index b8f0fdfd89..6b198d43b6 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLib.h
@@ -89,6 +89,8 @@ extern TEST_DESC mRsaPssTest[];
extern UINTN mBnTestNum;
extern TEST_DESC mBnTest[];
+extern UINTN mEcTestNum;
+extern TEST_DESC mEcTest[];
/** Creates a framework you can use */
EFI_STATUS
EFIAPI
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
index 1301345a13..8f96cf6c4a 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibHost.inf
@@ -38,6 +38,7 @@
RsaPssTests.c
ParallelhashTests.c
BnTests.c
+ EcTests.c
[Packages]
MdePkg/MdePkg.dec
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
index 9a41dbc317..c9a86dab98 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/TestBaseCryptLibShell.inf
@@ -37,6 +37,7 @@
OaepEncryptTests.c
RsaPssTests.c
BnTests.c
+ EcTests.c
[Packages]
MdePkg/MdePkg.dec
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* [PATCH 7/7] CryptoPkg: Run uncrustify tools on EC and BN change
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
` (5 preceding siblings ...)
2022-09-07 8:29 ` [PATCH 6/7] CryptoPkg/Test: Add unit test for CryptoEc yi1 li
@ 2022-09-07 8:29 ` yi1 li
2022-09-20 16:01 ` [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib Yao, Jiewen
7 siblings, 0 replies; 11+ messages in thread
From: yi1 li @ 2022-09-07 8:29 UTC (permalink / raw)
To: devel; +Cc: Yi Li, Jiewen Yao, Jian J Wang, Xiaoyu Lu, Guomin Jiang
Run uncrustify tools on EC and BN change to meet UEFI code style.
Cc: Jiewen Yao <jiewen.yao@intel.com>
Cc: Jian J Wang <jian.j.wang@intel.com>
Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
Cc: Guomin Jiang <guomin.jiang@intel.com>
Signed-off-by: Yi Li <yi1.li@intel.com>
---
CryptoPkg/Driver/Crypto.c | 2 +-
CryptoPkg/Include/Library/BaseCryptLib.h | 8 +-
CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c | 54 +--
CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c | 156 ++++----
CryptoPkg/Private/Protocol/Crypto.h | 368 +++++++++---------
.../UnitTest/Library/BaseCryptLib/BnTests.c | 109 +++---
.../UnitTest/Library/BaseCryptLib/EcTests.c | 93 ++---
7 files changed, 405 insertions(+), 385 deletions(-)
diff --git a/CryptoPkg/Driver/Crypto.c b/CryptoPkg/Driver/Crypto.c
index f7b9287218..9682a46778 100644
--- a/CryptoPkg/Driver/Crypto.c
+++ b/CryptoPkg/Driver/Crypto.c
@@ -5546,7 +5546,7 @@ CryptoServiceEcDhComputeKey (
IN OUT UINTN *KeySize
)
{
- return CALL_BASECRYPTLIB (Ec.Services.DhComputeKey, EcDhComputeKey, (EcContext, PeerPublic, PeerPublicSize, CompressFlag ,Key, KeySize), FALSE);
+ return CALL_BASECRYPTLIB (Ec.Services.DhComputeKey, EcDhComputeKey, (EcContext, PeerPublic, PeerPublicSize, CompressFlag, Key, KeySize), FALSE);
}
const EDKII_CRYPTO_PROTOCOL mEdkiiCrypto = {
diff --git a/CryptoPkg/Include/Library/BaseCryptLib.h b/CryptoPkg/Include/Library/BaseCryptLib.h
index ea3ed5270f..d74fc21c1e 100644
--- a/CryptoPkg/Include/Library/BaseCryptLib.h
+++ b/CryptoPkg/Include/Library/BaseCryptLib.h
@@ -14,12 +14,12 @@ SPDX-License-Identifier: BSD-2-Clause-Patent
#include <Uefi/UefiBaseType.h>
-#define CRYPTO_NID_NULL 0x0000
+#define CRYPTO_NID_NULL 0x0000
// Key Exchange
-#define CRYPTO_NID_SECP256R1 0x0204
-#define CRYPTO_NID_SECP384R1 0x0205
-#define CRYPTO_NID_SECP521R1 0x0206
+#define CRYPTO_NID_SECP256R1 0x0204
+#define CRYPTO_NID_SECP384R1 0x0205
+#define CRYPTO_NID_SECP521R1 0x0206
///
/// MD5 digest size in bytes
diff --git a/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
index 7a3043b1de..282926ddcc 100644
--- a/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
+++ b/CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
@@ -99,7 +99,7 @@ BigNumAdd (
OUT VOID *BnRes
)
{
- return (BOOLEAN) BN_add (BnRes, BnA, BnB);
+ return (BOOLEAN)BN_add (BnRes, BnA, BnB);
}
/**
@@ -122,7 +122,7 @@ BigNumSub (
OUT VOID *BnRes
)
{
- return (BOOLEAN) BN_sub (BnRes, BnA, BnB);
+ return (BOOLEAN)BN_sub (BnRes, BnA, BnB);
}
/**
@@ -145,15 +145,15 @@ BigNumMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_mod (BnRes, BnA, BnB, Ctx);
+ RetVal = (BOOLEAN)BN_mod (BnRes, BnA, BnB, Ctx);
BN_CTX_free (Ctx);
return RetVal;
@@ -181,15 +181,15 @@ BigNumExpMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_mod_exp (BnRes, BnA, BnP, BnM, Ctx);
+ RetVal = (BOOLEAN)BN_mod_exp (BnRes, BnA, BnP, BnM, Ctx);
BN_CTX_free (Ctx);
return RetVal;
@@ -215,8 +215,8 @@ BigNumInverseMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
@@ -226,7 +226,7 @@ BigNumInverseMod (
RetVal = FALSE;
if (BN_mod_inverse (BnRes, BnA, BnM, Ctx) != NULL) {
RetVal = TRUE;
- };
+ }
BN_CTX_free (Ctx);
return RetVal;
@@ -252,15 +252,15 @@ BigNumDiv (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_div (BnRes, NULL, BnA, BnB, Ctx);
+ RetVal = (BOOLEAN)BN_div (BnRes, NULL, BnA, BnB, Ctx);
BN_CTX_free (Ctx);
return RetVal;
@@ -288,15 +288,15 @@ BigNumMulMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_mod_mul (BnRes, BnA, BnB, BnM, Ctx);
+ RetVal = (BOOLEAN)BN_mod_mul (BnRes, BnA, BnB, BnM, Ctx);
BN_CTX_free (Ctx);
return RetVal;
@@ -370,7 +370,7 @@ BigNumIsWord (
IN UINTN Num
)
{
- return (BOOLEAN) BN_is_word (Bn, Num);
+ return (BOOLEAN)BN_is_word (Bn, Num);
}
/**
@@ -387,7 +387,7 @@ BigNumIsOdd (
IN CONST VOID *Bn
)
{
- return (BOOLEAN) BN_is_odd (Bn);
+ return (BOOLEAN)BN_is_odd (Bn);
}
/**
@@ -444,7 +444,7 @@ BigNumRShift (
OUT VOID *BnRes
)
{
- return (BOOLEAN) BN_rshift (BnRes, Bn, (INT32) N);
+ return (BOOLEAN)BN_rshift (BnRes, Bn, (INT32)N);
}
/**
@@ -483,15 +483,15 @@ BigNumSqrMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_mod_sqr (BnRes, BnA, BnM, Ctx);
+ RetVal = (BOOLEAN)BN_mod_sqr (BnRes, BnA, BnM, Ctx);
BN_CTX_free (Ctx);
return RetVal;
@@ -543,7 +543,7 @@ BigNumSetUint (
IN UINTN Val
)
{
- return (BOOLEAN) BN_set_word (Bn, Val);
+ return (BOOLEAN)BN_set_word (Bn, Val);
}
/**
@@ -566,15 +566,15 @@ BigNumAddMod (
OUT VOID *BnRes
)
{
- BOOLEAN RetVal;
- BN_CTX *Ctx;
+ BOOLEAN RetVal;
+ BN_CTX *Ctx;
Ctx = BN_CTX_new ();
if (Ctx == NULL) {
return FALSE;
}
- RetVal = (BOOLEAN) BN_mod_add (BnRes, BnA, BnB, BnM, Ctx);
+ RetVal = (BOOLEAN)BN_mod_add (BnRes, BnA, BnB, BnM, Ctx);
BN_CTX_free (Ctx);
return RetVal;
diff --git a/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
index e9b0391a56..396c819834 100644
--- a/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
+++ b/CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
@@ -27,8 +27,8 @@
STATIC
INT32
CryptoNidToOpensslNid (
- IN UINTN CryptoNid
-)
+ IN UINTN CryptoNid
+ )
{
INT32 Nid;
@@ -102,7 +102,7 @@ EcGroupGetCurve (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_GROUP_get_curve (EcGroup, BnPrime, BnA, BnB, BnCtx);
+ return (BOOLEAN)EC_GROUP_get_curve (EcGroup, BnPrime, BnA, BnB, BnCtx);
}
/**
@@ -124,7 +124,7 @@ EcGroupGetOrder (
OUT VOID *BnOrder
)
{
- return (BOOLEAN) EC_GROUP_get_order (EcGroup, BnOrder, NULL);
+ return (BOOLEAN)EC_GROUP_get_order (EcGroup, BnOrder, NULL);
}
/**
@@ -204,7 +204,7 @@ EcPointGetAffineCoordinates (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_get_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
+ return (BOOLEAN)EC_POINT_get_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
}
/**
@@ -229,7 +229,7 @@ EcPointSetAffineCoordinates (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_set_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
+ return (BOOLEAN)EC_POINT_set_affine_coordinates (EcGroup, EcPoint, BnX, BnY, BnCtx);
}
/**
@@ -255,7 +255,7 @@ EcPointAdd (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_add (EcGroup, EcPointResult, EcPointA, EcPointB, BnCtx);
+ return (BOOLEAN)EC_POINT_add (EcGroup, EcPointResult, EcPointA, EcPointB, BnCtx);
}
/**
@@ -281,7 +281,7 @@ EcPointMul (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_mul (EcGroup, EcPointResult, NULL, EcPoint, BnPScalar, BnCtx);
+ return (BOOLEAN)EC_POINT_mul (EcGroup, EcPointResult, NULL, EcPoint, BnPScalar, BnCtx);
}
/**
@@ -302,7 +302,7 @@ EcPointInvert (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_invert (EcGroup, EcPoint, BnCtx);
+ return (BOOLEAN)EC_POINT_invert (EcGroup, EcPoint, BnCtx);
}
/**
@@ -395,7 +395,7 @@ EcPointSetCompressedCoordinates (
IN VOID *BnCtx
)
{
- return (BOOLEAN) EC_POINT_set_compressed_coordinates (EcGroup, EcPoint, BnX, YBit, BnCtx);
+ return (BOOLEAN)EC_POINT_set_compressed_coordinates (EcGroup, EcPoint, BnX, YBit, BnCtx);
}
// =====================================================================================
@@ -417,7 +417,7 @@ EcNewByNid (
IN UINTN Nid
)
{
- INT32 OpenSslNid;
+ INT32 OpenSslNid;
OpenSslNid = CryptoNidToOpensslNid (Nid);
if (OpenSslNid < 0) {
@@ -438,7 +438,7 @@ EcFree (
IN VOID *EcContext
)
{
- EC_KEY_free ((EC_KEY *) EcContext);
+ EC_KEY_free ((EC_KEY *)EcContext);
}
/**
@@ -475,26 +475,26 @@ EcGenerateKey (
IN OUT UINTN *PublicKeySize
)
{
- EC_KEY *EcKey;
- CONST EC_GROUP *Group;
- CONST EC_POINT *EcPoint;
- BOOLEAN RetVal;
- BIGNUM *BnX;
- BIGNUM *BnY;
- UINTN HalfSize;
- INTN XSize;
- INTN YSize;
-
- if (EcContext == NULL || PublicKeySize == NULL) {
+ EC_KEY *EcKey;
+ CONST EC_GROUP *Group;
+ CONST EC_POINT *EcPoint;
+ BOOLEAN RetVal;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ UINTN HalfSize;
+ INTN XSize;
+ INTN YSize;
+
+ if ((EcContext == NULL) || (PublicKeySize == NULL)) {
return FALSE;
}
- if (PublicKey == NULL && *PublicKeySize != 0) {
+ if ((PublicKey == NULL) && (*PublicKeySize != 0)) {
return FALSE;
}
- EcKey = (EC_KEY *)EcContext;
- Group = EC_KEY_get0_group (EcKey);
+ EcKey = (EC_KEY *)EcContext;
+ Group = EC_KEY_get0_group (EcKey);
HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
// Assume RAND_seed was called
@@ -506,6 +506,7 @@ EcGenerateKey (
*PublicKeySize = HalfSize * 2;
return FALSE;
}
+
*PublicKeySize = HalfSize * 2;
EcPoint = EC_KEY_get0_public_key (EcKey);
@@ -514,9 +515,9 @@ EcGenerateKey (
}
RetVal = FALSE;
- BnX = BN_new();
- BnY = BN_new();
- if (BnX == NULL || BnY == NULL) {
+ BnX = BN_new ();
+ BnY = BN_new ();
+ if ((BnX == NULL) || (BnY == NULL)) {
goto fail;
}
@@ -526,9 +527,10 @@ EcGenerateKey (
XSize = BN_num_bytes (BnX);
YSize = BN_num_bytes (BnY);
- if (XSize <= 0 || YSize <= 0) {
+ if ((XSize <= 0) || (YSize <= 0)) {
goto fail;
}
+
ASSERT ((UINTN)XSize <= HalfSize && (UINTN)YSize <= HalfSize);
ZeroMem (PublicKey, *PublicKeySize);
@@ -565,31 +567,32 @@ EcGetPubKey (
IN OUT UINTN *PublicKeySize
)
{
- EC_KEY *EcKey;
- CONST EC_GROUP *Group;
- CONST EC_POINT *EcPoint;
- BIGNUM *BnX;
- BIGNUM *BnY;
- UINTN HalfSize;
- INTN XSize;
- INTN YSize;
- BOOLEAN RetVal;
-
- if (EcContext == NULL || PublicKeySize == NULL) {
+ EC_KEY *EcKey;
+ CONST EC_GROUP *Group;
+ CONST EC_POINT *EcPoint;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ UINTN HalfSize;
+ INTN XSize;
+ INTN YSize;
+ BOOLEAN RetVal;
+
+ if ((EcContext == NULL) || (PublicKeySize == NULL)) {
return FALSE;
}
- if (PublicKey == NULL && *PublicKeySize != 0) {
+ if ((PublicKey == NULL) && (*PublicKeySize != 0)) {
return FALSE;
}
- EcKey = (EC_KEY *)EcContext;
- Group = EC_KEY_get0_group (EcKey);
+ EcKey = (EC_KEY *)EcContext;
+ Group = EC_KEY_get0_group (EcKey);
HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
if (*PublicKeySize < HalfSize * 2) {
*PublicKeySize = HalfSize * 2;
return FALSE;
}
+
*PublicKeySize = HalfSize * 2;
EcPoint = EC_KEY_get0_public_key (EcKey);
@@ -598,9 +601,9 @@ EcGetPubKey (
}
RetVal = FALSE;
- BnX = BN_new();
- BnY = BN_new();
- if (BnX == NULL || BnY == NULL) {
+ BnX = BN_new ();
+ BnY = BN_new ();
+ if ((BnX == NULL) || (BnY == NULL)) {
goto fail;
}
@@ -610,9 +613,10 @@ EcGetPubKey (
XSize = BN_num_bytes (BnX);
YSize = BN_num_bytes (BnY);
- if (XSize <= 0 || YSize <= 0) {
+ if ((XSize <= 0) || (YSize <= 0)) {
goto fail;
}
+
ASSERT ((UINTN)XSize <= HalfSize && (UINTN)YSize <= HalfSize);
if (PublicKey != NULL) {
@@ -666,21 +670,21 @@ EcDhComputeKey (
IN OUT UINTN *KeySize
)
{
- EC_KEY *EcKey;
- EC_KEY *PeerEcKey;
- CONST EC_GROUP *Group;
- BOOLEAN RetVal;
- BIGNUM *BnX;
- BIGNUM *BnY;
- EC_POINT *Point;
- INT32 OpenSslNid;
- UINTN HalfSize;
-
- if (EcContext == NULL || PeerPublic == NULL || KeySize == NULL) {
+ EC_KEY *EcKey;
+ EC_KEY *PeerEcKey;
+ CONST EC_GROUP *Group;
+ BOOLEAN RetVal;
+ BIGNUM *BnX;
+ BIGNUM *BnY;
+ EC_POINT *Point;
+ INT32 OpenSslNid;
+ UINTN HalfSize;
+
+ if ((EcContext == NULL) || (PeerPublic == NULL) || (KeySize == NULL)) {
return FALSE;
}
- if (Key == NULL && *KeySize != 0) {
+ if ((Key == NULL) && (*KeySize != 0)) {
return FALSE;
}
@@ -688,36 +692,40 @@ EcDhComputeKey (
return FALSE;
}
- EcKey = (EC_KEY *) EcContext;
- Group = EC_KEY_get0_group (EcKey);
+ EcKey = (EC_KEY *)EcContext;
+ Group = EC_KEY_get0_group (EcKey);
HalfSize = (EC_GROUP_get_degree (Group) + 7) / 8;
- if (CompressFlag == NULL && PeerPublicSize != HalfSize * 2) {
+ if ((CompressFlag == NULL) && (PeerPublicSize != HalfSize * 2)) {
return FALSE;
}
- if (CompressFlag != NULL && PeerPublicSize != HalfSize) {
+
+ if ((CompressFlag != NULL) && (PeerPublicSize != HalfSize)) {
return FALSE;
}
+
if (*KeySize < HalfSize) {
*KeySize = HalfSize;
return FALSE;
}
+
*KeySize = HalfSize;
- RetVal = FALSE;
- Point = NULL;
- BnX = BN_bin2bn (PeerPublic, (INT32) HalfSize, NULL);
- BnY = NULL;
- Point = EC_POINT_new (Group);
+ RetVal = FALSE;
+ Point = NULL;
+ BnX = BN_bin2bn (PeerPublic, (INT32)HalfSize, NULL);
+ BnY = NULL;
+ Point = EC_POINT_new (Group);
PeerEcKey = NULL;
- if (BnX == NULL || Point == NULL) {
+ if ((BnX == NULL) || (Point == NULL)) {
goto fail;
}
if (CompressFlag == NULL) {
- BnY = BN_bin2bn (PeerPublic + HalfSize, (INT32) HalfSize, NULL);
+ BnY = BN_bin2bn (PeerPublic + HalfSize, (INT32)HalfSize, NULL);
if (BnY == NULL) {
goto fail;
}
+
if (EC_POINT_set_affine_coordinates (Group, Point, BnX, BnY, NULL) != 1) {
goto fail;
}
@@ -729,13 +737,15 @@ EcDhComputeKey (
// Validate NIST ECDH public key
OpenSslNid = EC_GROUP_get_curve_name (Group);
- PeerEcKey = EC_KEY_new_by_curve_name (OpenSslNid);
+ PeerEcKey = EC_KEY_new_by_curve_name (OpenSslNid);
if (PeerEcKey == NULL) {
goto fail;
}
+
if (EC_KEY_set_public_key (PeerEcKey, Point) != 1) {
goto fail;
}
+
if (EC_KEY_check_key (PeerEcKey) != 1) {
goto fail;
}
@@ -749,7 +759,7 @@ EcDhComputeKey (
fail:
BN_free (BnX);
BN_free (BnY);
- EC_POINT_free(Point);
+ EC_POINT_free (Point);
EC_KEY_free (PeerEcKey);
return RetVal;
}
diff --git a/CryptoPkg/Private/Protocol/Crypto.h b/CryptoPkg/Private/Protocol/Crypto.h
index 84d9fbba32..a91f97b0c0 100644
--- a/CryptoPkg/Private/Protocol/Crypto.h
+++ b/CryptoPkg/Private/Protocol/Crypto.h
@@ -4302,216 +4302,216 @@ BOOLEAN
///
struct _EDKII_CRYPTO_PROTOCOL {
/// Version
- EDKII_CRYPTO_GET_VERSION GetVersion;
+ EDKII_CRYPTO_GET_VERSION GetVersion;
/// HMAC MD5 - deprecated and unsupported
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_NEW DeprecatedHmacMd5New;
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_FREE DeprecatedHmacMd5Free;
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_SET_KEY DeprecatedHmacMd5SetKey;
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_DUPLICATE DeprecatedHmacMd5Duplicate;
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_UPDATE DeprecatedHmacMd5Update;
- DEPRECATED_EDKII_CRYPTO_HMAC_MD5_FINAL DeprecatedHmacMd5Final;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_NEW DeprecatedHmacMd5New;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_FREE DeprecatedHmacMd5Free;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_SET_KEY DeprecatedHmacMd5SetKey;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_DUPLICATE DeprecatedHmacMd5Duplicate;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_UPDATE DeprecatedHmacMd5Update;
+ DEPRECATED_EDKII_CRYPTO_HMAC_MD5_FINAL DeprecatedHmacMd5Final;
/// HMAC SHA1 - deprecated and unsupported
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_NEW DeprecatedHmacSha1New;
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_FREE DeprecatedHmacSha1Free;
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_SET_KEY DeprecatedHmacSha1SetKey;
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_DUPLICATE DeprecatedHmacSha1Duplicate;
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_UPDATE DeprecatedHmacSha1Update;
- DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_FINAL DeprecatedHmacSha1Final;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_NEW DeprecatedHmacSha1New;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_FREE DeprecatedHmacSha1Free;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_SET_KEY DeprecatedHmacSha1SetKey;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_DUPLICATE DeprecatedHmacSha1Duplicate;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_UPDATE DeprecatedHmacSha1Update;
+ DEPRECATED_EDKII_CRYPTO_HMAC_SHA1_FINAL DeprecatedHmacSha1Final;
/// HMAC SHA256
- EDKII_CRYPTO_HMAC_SHA256_NEW HmacSha256New;
- EDKII_CRYPTO_HMAC_SHA256_FREE HmacSha256Free;
- EDKII_CRYPTO_HMAC_SHA256_SET_KEY HmacSha256SetKey;
- EDKII_CRYPTO_HMAC_SHA256_DUPLICATE HmacSha256Duplicate;
- EDKII_CRYPTO_HMAC_SHA256_UPDATE HmacSha256Update;
- EDKII_CRYPTO_HMAC_SHA256_FINAL HmacSha256Final;
+ EDKII_CRYPTO_HMAC_SHA256_NEW HmacSha256New;
+ EDKII_CRYPTO_HMAC_SHA256_FREE HmacSha256Free;
+ EDKII_CRYPTO_HMAC_SHA256_SET_KEY HmacSha256SetKey;
+ EDKII_CRYPTO_HMAC_SHA256_DUPLICATE HmacSha256Duplicate;
+ EDKII_CRYPTO_HMAC_SHA256_UPDATE HmacSha256Update;
+ EDKII_CRYPTO_HMAC_SHA256_FINAL HmacSha256Final;
/// Md4 - deprecated and unsupported
- DEPRECATED_EDKII_CRYPTO_MD4_GET_CONTEXT_SIZE DeprecatedMd4GetContextSize;
- DEPRECATED_EDKII_CRYPTO_MD4_INIT DeprecatedMd4Init;
- DEPRECATED_EDKII_CRYPTO_MD4_DUPLICATE DeprecatedMd4Duplicate;
- DEPRECATED_EDKII_CRYPTO_MD4_UPDATE DeprecatedMd4Update;
- DEPRECATED_EDKII_CRYPTO_MD4_FINAL DeprecatedMd4Final;
- DEPRECATED_EDKII_CRYPTO_MD4_HASH_ALL DeprecatedMd4HashAll;
+ DEPRECATED_EDKII_CRYPTO_MD4_GET_CONTEXT_SIZE DeprecatedMd4GetContextSize;
+ DEPRECATED_EDKII_CRYPTO_MD4_INIT DeprecatedMd4Init;
+ DEPRECATED_EDKII_CRYPTO_MD4_DUPLICATE DeprecatedMd4Duplicate;
+ DEPRECATED_EDKII_CRYPTO_MD4_UPDATE DeprecatedMd4Update;
+ DEPRECATED_EDKII_CRYPTO_MD4_FINAL DeprecatedMd4Final;
+ DEPRECATED_EDKII_CRYPTO_MD4_HASH_ALL DeprecatedMd4HashAll;
/// Md5
- EDKII_CRYPTO_MD5_GET_CONTEXT_SIZE Md5GetContextSize;
- EDKII_CRYPTO_MD5_INIT Md5Init;
- EDKII_CRYPTO_MD5_DUPLICATE Md5Duplicate;
- EDKII_CRYPTO_MD5_UPDATE Md5Update;
- EDKII_CRYPTO_MD5_FINAL Md5Final;
- EDKII_CRYPTO_MD5_HASH_ALL Md5HashAll;
+ EDKII_CRYPTO_MD5_GET_CONTEXT_SIZE Md5GetContextSize;
+ EDKII_CRYPTO_MD5_INIT Md5Init;
+ EDKII_CRYPTO_MD5_DUPLICATE Md5Duplicate;
+ EDKII_CRYPTO_MD5_UPDATE Md5Update;
+ EDKII_CRYPTO_MD5_FINAL Md5Final;
+ EDKII_CRYPTO_MD5_HASH_ALL Md5HashAll;
/// Pkcs
- EDKII_CRYPTO_PKCS1_ENCRYPT_V2 Pkcs1v2Encrypt;
- EDKII_CRYPTO_PKCS5_PW_HASH Pkcs5HashPassword;
- EDKII_CRYPTO_PKCS7_VERIFY Pkcs7Verify;
- EDKII_CRYPTO_PKCS7_VERIFY_EKU VerifyEKUsInPkcs7Signature;
- EDKII_CRYPTO_PKCS7_GET_SIGNERS Pkcs7GetSigners;
- EDKII_CRYPTO_PKCS7_FREE_SIGNERS Pkcs7FreeSigners;
- EDKII_CRYPTO_PKCS7_SIGN Pkcs7Sign;
- EDKII_CRYPTO_PKCS7_GET_ATTACHED_CONTENT Pkcs7GetAttachedContent;
- EDKII_CRYPTO_PKCS7_GET_CERTIFICATES_LIST Pkcs7GetCertificatesList;
- EDKII_CRYPTO_AUTHENTICODE_VERIFY AuthenticodeVerify;
- EDKII_CRYPTO_IMAGE_TIMESTAMP_VERIFY ImageTimestampVerify;
+ EDKII_CRYPTO_PKCS1_ENCRYPT_V2 Pkcs1v2Encrypt;
+ EDKII_CRYPTO_PKCS5_PW_HASH Pkcs5HashPassword;
+ EDKII_CRYPTO_PKCS7_VERIFY Pkcs7Verify;
+ EDKII_CRYPTO_PKCS7_VERIFY_EKU VerifyEKUsInPkcs7Signature;
+ EDKII_CRYPTO_PKCS7_GET_SIGNERS Pkcs7GetSigners;
+ EDKII_CRYPTO_PKCS7_FREE_SIGNERS Pkcs7FreeSigners;
+ EDKII_CRYPTO_PKCS7_SIGN Pkcs7Sign;
+ EDKII_CRYPTO_PKCS7_GET_ATTACHED_CONTENT Pkcs7GetAttachedContent;
+ EDKII_CRYPTO_PKCS7_GET_CERTIFICATES_LIST Pkcs7GetCertificatesList;
+ EDKII_CRYPTO_AUTHENTICODE_VERIFY AuthenticodeVerify;
+ EDKII_CRYPTO_IMAGE_TIMESTAMP_VERIFY ImageTimestampVerify;
/// DH
- EDKII_CRYPTO_DH_NEW DhNew;
- EDKII_CRYPTO_DH_FREE DhFree;
- EDKII_CRYPTO_DH_GENERATE_PARAMETER DhGenerateParameter;
- EDKII_CRYPTO_DH_SET_PARAMETER DhSetParameter;
- EDKII_CRYPTO_DH_GENERATE_KEY DhGenerateKey;
- EDKII_CRYPTO_DH_COMPUTE_KEY DhComputeKey;
+ EDKII_CRYPTO_DH_NEW DhNew;
+ EDKII_CRYPTO_DH_FREE DhFree;
+ EDKII_CRYPTO_DH_GENERATE_PARAMETER DhGenerateParameter;
+ EDKII_CRYPTO_DH_SET_PARAMETER DhSetParameter;
+ EDKII_CRYPTO_DH_GENERATE_KEY DhGenerateKey;
+ EDKII_CRYPTO_DH_COMPUTE_KEY DhComputeKey;
/// Random
- EDKII_CRYPTO_RANDOM_SEED RandomSeed;
- EDKII_CRYPTO_RANDOM_BYTES RandomBytes;
+ EDKII_CRYPTO_RANDOM_SEED RandomSeed;
+ EDKII_CRYPTO_RANDOM_BYTES RandomBytes;
/// RSA
- EDKII_CRYPTO_RSA_VERIFY_PKCS1 RsaVerifyPkcs1;
- EDKII_CRYPTO_RSA_NEW RsaNew;
- EDKII_CRYPTO_RSA_FREE RsaFree;
- EDKII_CRYPTO_RSA_SET_KEY RsaSetKey;
- EDKII_CRYPTO_RSA_GET_KEY RsaGetKey;
- EDKII_CRYPTO_RSA_GENERATE_KEY RsaGenerateKey;
- EDKII_CRYPTO_RSA_CHECK_KEY RsaCheckKey;
- EDKII_CRYPTO_RSA_PKCS1_SIGN RsaPkcs1Sign;
- EDKII_CRYPTO_RSA_PKCS1_VERIFY RsaPkcs1Verify;
- EDKII_CRYPTO_RSA_GET_PRIVATE_KEY_FROM_PEM RsaGetPrivateKeyFromPem;
- EDKII_CRYPTO_RSA_GET_PUBLIC_KEY_FROM_X509 RsaGetPublicKeyFromX509;
+ EDKII_CRYPTO_RSA_VERIFY_PKCS1 RsaVerifyPkcs1;
+ EDKII_CRYPTO_RSA_NEW RsaNew;
+ EDKII_CRYPTO_RSA_FREE RsaFree;
+ EDKII_CRYPTO_RSA_SET_KEY RsaSetKey;
+ EDKII_CRYPTO_RSA_GET_KEY RsaGetKey;
+ EDKII_CRYPTO_RSA_GENERATE_KEY RsaGenerateKey;
+ EDKII_CRYPTO_RSA_CHECK_KEY RsaCheckKey;
+ EDKII_CRYPTO_RSA_PKCS1_SIGN RsaPkcs1Sign;
+ EDKII_CRYPTO_RSA_PKCS1_VERIFY RsaPkcs1Verify;
+ EDKII_CRYPTO_RSA_GET_PRIVATE_KEY_FROM_PEM RsaGetPrivateKeyFromPem;
+ EDKII_CRYPTO_RSA_GET_PUBLIC_KEY_FROM_X509 RsaGetPublicKeyFromX509;
/// Sha1
- EDKII_CRYPTO_SHA1_GET_CONTEXT_SIZE Sha1GetContextSize;
- EDKII_CRYPTO_SHA1_INIT Sha1Init;
- EDKII_CRYPTO_SHA1_DUPLICATE Sha1Duplicate;
- EDKII_CRYPTO_SHA1_UPDATE Sha1Update;
- EDKII_CRYPTO_SHA1_FINAL Sha1Final;
- EDKII_CRYPTO_SHA1_HASH_ALL Sha1HashAll;
+ EDKII_CRYPTO_SHA1_GET_CONTEXT_SIZE Sha1GetContextSize;
+ EDKII_CRYPTO_SHA1_INIT Sha1Init;
+ EDKII_CRYPTO_SHA1_DUPLICATE Sha1Duplicate;
+ EDKII_CRYPTO_SHA1_UPDATE Sha1Update;
+ EDKII_CRYPTO_SHA1_FINAL Sha1Final;
+ EDKII_CRYPTO_SHA1_HASH_ALL Sha1HashAll;
/// Sha256
- EDKII_CRYPTO_SHA256_GET_CONTEXT_SIZE Sha256GetContextSize;
- EDKII_CRYPTO_SHA256_INIT Sha256Init;
- EDKII_CRYPTO_SHA256_DUPLICATE Sha256Duplicate;
- EDKII_CRYPTO_SHA256_UPDATE Sha256Update;
- EDKII_CRYPTO_SHA256_FINAL Sha256Final;
- EDKII_CRYPTO_SHA256_HASH_ALL Sha256HashAll;
+ EDKII_CRYPTO_SHA256_GET_CONTEXT_SIZE Sha256GetContextSize;
+ EDKII_CRYPTO_SHA256_INIT Sha256Init;
+ EDKII_CRYPTO_SHA256_DUPLICATE Sha256Duplicate;
+ EDKII_CRYPTO_SHA256_UPDATE Sha256Update;
+ EDKII_CRYPTO_SHA256_FINAL Sha256Final;
+ EDKII_CRYPTO_SHA256_HASH_ALL Sha256HashAll;
/// Sha384
- EDKII_CRYPTO_SHA384_GET_CONTEXT_SIZE Sha384GetContextSize;
- EDKII_CRYPTO_SHA384_INIT Sha384Init;
- EDKII_CRYPTO_SHA384_DUPLICATE Sha384Duplicate;
- EDKII_CRYPTO_SHA384_UPDATE Sha384Update;
- EDKII_CRYPTO_SHA384_FINAL Sha384Final;
- EDKII_CRYPTO_SHA384_HASH_ALL Sha384HashAll;
+ EDKII_CRYPTO_SHA384_GET_CONTEXT_SIZE Sha384GetContextSize;
+ EDKII_CRYPTO_SHA384_INIT Sha384Init;
+ EDKII_CRYPTO_SHA384_DUPLICATE Sha384Duplicate;
+ EDKII_CRYPTO_SHA384_UPDATE Sha384Update;
+ EDKII_CRYPTO_SHA384_FINAL Sha384Final;
+ EDKII_CRYPTO_SHA384_HASH_ALL Sha384HashAll;
/// Sha512
- EDKII_CRYPTO_SHA512_GET_CONTEXT_SIZE Sha512GetContextSize;
- EDKII_CRYPTO_SHA512_INIT Sha512Init;
- EDKII_CRYPTO_SHA512_DUPLICATE Sha512Duplicate;
- EDKII_CRYPTO_SHA512_UPDATE Sha512Update;
- EDKII_CRYPTO_SHA512_FINAL Sha512Final;
- EDKII_CRYPTO_SHA512_HASH_ALL Sha512HashAll;
+ EDKII_CRYPTO_SHA512_GET_CONTEXT_SIZE Sha512GetContextSize;
+ EDKII_CRYPTO_SHA512_INIT Sha512Init;
+ EDKII_CRYPTO_SHA512_DUPLICATE Sha512Duplicate;
+ EDKII_CRYPTO_SHA512_UPDATE Sha512Update;
+ EDKII_CRYPTO_SHA512_FINAL Sha512Final;
+ EDKII_CRYPTO_SHA512_HASH_ALL Sha512HashAll;
/// X509
- EDKII_CRYPTO_X509_GET_SUBJECT_NAME X509GetSubjectName;
- EDKII_CRYPTO_X509_GET_COMMON_NAME X509GetCommonName;
- EDKII_CRYPTO_X509_GET_ORGANIZATION_NAME X509GetOrganizationName;
- EDKII_CRYPTO_X509_VERIFY_CERT X509VerifyCert;
- EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE X509ConstructCertificate;
- EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE_STACK X509ConstructCertificateStack;
- EDKII_CRYPTO_X509_FREE X509Free;
- EDKII_CRYPTO_X509_STACK_FREE X509StackFree;
- EDKII_CRYPTO_X509_GET_TBS_CERT X509GetTBSCert;
+ EDKII_CRYPTO_X509_GET_SUBJECT_NAME X509GetSubjectName;
+ EDKII_CRYPTO_X509_GET_COMMON_NAME X509GetCommonName;
+ EDKII_CRYPTO_X509_GET_ORGANIZATION_NAME X509GetOrganizationName;
+ EDKII_CRYPTO_X509_VERIFY_CERT X509VerifyCert;
+ EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE X509ConstructCertificate;
+ EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE_STACK X509ConstructCertificateStack;
+ EDKII_CRYPTO_X509_FREE X509Free;
+ EDKII_CRYPTO_X509_STACK_FREE X509StackFree;
+ EDKII_CRYPTO_X509_GET_TBS_CERT X509GetTBSCert;
/// TDES - deprecated and unsupported
- DEPRECATED_EDKII_CRYPTO_TDES_GET_CONTEXT_SIZE DeprecatedTdesGetContextSize;
- DEPRECATED_EDKII_CRYPTO_TDES_INIT DeprecatedTdesInit;
- DEPRECATED_EDKII_CRYPTO_TDES_ECB_ENCRYPT DeprecatedTdesEcbEncrypt;
- DEPRECATED_EDKII_CRYPTO_TDES_ECB_DECRYPT DeprecatedTdesEcbDecrypt;
- DEPRECATED_EDKII_CRYPTO_TDES_CBC_ENCRYPT DeprecatedTdesCbcEncrypt;
- DEPRECATED_EDKII_CRYPTO_TDES_CBC_DECRYPT DeprecatedTdesCbcDecrypt;
+ DEPRECATED_EDKII_CRYPTO_TDES_GET_CONTEXT_SIZE DeprecatedTdesGetContextSize;
+ DEPRECATED_EDKII_CRYPTO_TDES_INIT DeprecatedTdesInit;
+ DEPRECATED_EDKII_CRYPTO_TDES_ECB_ENCRYPT DeprecatedTdesEcbEncrypt;
+ DEPRECATED_EDKII_CRYPTO_TDES_ECB_DECRYPT DeprecatedTdesEcbDecrypt;
+ DEPRECATED_EDKII_CRYPTO_TDES_CBC_ENCRYPT DeprecatedTdesCbcEncrypt;
+ DEPRECATED_EDKII_CRYPTO_TDES_CBC_DECRYPT DeprecatedTdesCbcDecrypt;
/// AES - ECB Mode is deprecated and unsupported
- EDKII_CRYPTO_AES_GET_CONTEXT_SIZE AesGetContextSize;
- EDKII_CRYPTO_AES_INIT AesInit;
- DEPRECATED_EDKII_CRYPTO_AES_ECB_ENCRYPT DeprecatedAesEcbEncrypt;
- DEPRECATED_EDKII_CRYPTO_AES_ECB_DECRYPT DeprecatedAesEcbDecrypt;
- EDKII_CRYPTO_AES_CBC_ENCRYPT AesCbcEncrypt;
- EDKII_CRYPTO_AES_CBC_DECRYPT AesCbcDecrypt;
+ EDKII_CRYPTO_AES_GET_CONTEXT_SIZE AesGetContextSize;
+ EDKII_CRYPTO_AES_INIT AesInit;
+ DEPRECATED_EDKII_CRYPTO_AES_ECB_ENCRYPT DeprecatedAesEcbEncrypt;
+ DEPRECATED_EDKII_CRYPTO_AES_ECB_DECRYPT DeprecatedAesEcbDecrypt;
+ EDKII_CRYPTO_AES_CBC_ENCRYPT AesCbcEncrypt;
+ EDKII_CRYPTO_AES_CBC_DECRYPT AesCbcDecrypt;
/// Arc4 - deprecated and unsupported
- DEPRECATED_EDKII_CRYPTO_ARC4_GET_CONTEXT_SIZE DeprecatedArc4GetContextSize;
- DEPRECATED_EDKII_CRYPTO_ARC4_INIT DeprecatedArc4Init;
- DEPRECATED_EDKII_CRYPTO_ARC4_ENCRYPT DeprecatedArc4Encrypt;
- DEPRECATED_EDKII_CRYPTO_ARC4_DECRYPT DeprecatedArc4Decrypt;
- DEPRECATED_EDKII_CRYPTO_ARC4_RESET DeprecatedArc4Reset;
+ DEPRECATED_EDKII_CRYPTO_ARC4_GET_CONTEXT_SIZE DeprecatedArc4GetContextSize;
+ DEPRECATED_EDKII_CRYPTO_ARC4_INIT DeprecatedArc4Init;
+ DEPRECATED_EDKII_CRYPTO_ARC4_ENCRYPT DeprecatedArc4Encrypt;
+ DEPRECATED_EDKII_CRYPTO_ARC4_DECRYPT DeprecatedArc4Decrypt;
+ DEPRECATED_EDKII_CRYPTO_ARC4_RESET DeprecatedArc4Reset;
/// SM3
- EDKII_CRYPTO_SM3_GET_CONTEXT_SIZE Sm3GetContextSize;
- EDKII_CRYPTO_SM3_INIT Sm3Init;
- EDKII_CRYPTO_SM3_DUPLICATE Sm3Duplicate;
- EDKII_CRYPTO_SM3_UPDATE Sm3Update;
- EDKII_CRYPTO_SM3_FINAL Sm3Final;
- EDKII_CRYPTO_SM3_HASH_ALL Sm3HashAll;
+ EDKII_CRYPTO_SM3_GET_CONTEXT_SIZE Sm3GetContextSize;
+ EDKII_CRYPTO_SM3_INIT Sm3Init;
+ EDKII_CRYPTO_SM3_DUPLICATE Sm3Duplicate;
+ EDKII_CRYPTO_SM3_UPDATE Sm3Update;
+ EDKII_CRYPTO_SM3_FINAL Sm3Final;
+ EDKII_CRYPTO_SM3_HASH_ALL Sm3HashAll;
/// HKDF
- EDKII_CRYPTO_HKDF_SHA_256_EXTRACT_AND_EXPAND HkdfSha256ExtractAndExpand;
+ EDKII_CRYPTO_HKDF_SHA_256_EXTRACT_AND_EXPAND HkdfSha256ExtractAndExpand;
/// X509 (Continued)
- EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE_STACK_V X509ConstructCertificateStackV;
+ EDKII_CRYPTO_X509_CONSTRUCT_CERTIFICATE_STACK_V X509ConstructCertificateStackV;
/// TLS
- EDKII_CRYPTO_TLS_INITIALIZE TlsInitialize;
- EDKII_CRYPTO_TLS_CTX_FREE TlsCtxFree;
- EDKII_CRYPTO_TLS_CTX_NEW TlsCtxNew;
- EDKII_CRYPTO_TLS_FREE TlsFree;
- EDKII_CRYPTO_TLS_NEW TlsNew;
- EDKII_CRYPTO_TLS_IN_HANDSHAKE TlsInHandshake;
- EDKII_CRYPTO_TLS_DO_HANDSHAKE TlsDoHandshake;
- EDKII_CRYPTO_TLS_HANDLE_ALERT TlsHandleAlert;
- EDKII_CRYPTO_TLS_CLOSE_NOTIFY TlsCloseNotify;
- EDKII_CRYPTO_TLS_CTRL_TRAFFIC_OUT TlsCtrlTrafficOut;
- EDKII_CRYPTO_TLS_CTRL_TRAFFIC_IN TlsCtrlTrafficIn;
- EDKII_CRYPTO_TLS_READ TlsRead;
- EDKII_CRYPTO_TLS_WRITE TlsWrite;
+ EDKII_CRYPTO_TLS_INITIALIZE TlsInitialize;
+ EDKII_CRYPTO_TLS_CTX_FREE TlsCtxFree;
+ EDKII_CRYPTO_TLS_CTX_NEW TlsCtxNew;
+ EDKII_CRYPTO_TLS_FREE TlsFree;
+ EDKII_CRYPTO_TLS_NEW TlsNew;
+ EDKII_CRYPTO_TLS_IN_HANDSHAKE TlsInHandshake;
+ EDKII_CRYPTO_TLS_DO_HANDSHAKE TlsDoHandshake;
+ EDKII_CRYPTO_TLS_HANDLE_ALERT TlsHandleAlert;
+ EDKII_CRYPTO_TLS_CLOSE_NOTIFY TlsCloseNotify;
+ EDKII_CRYPTO_TLS_CTRL_TRAFFIC_OUT TlsCtrlTrafficOut;
+ EDKII_CRYPTO_TLS_CTRL_TRAFFIC_IN TlsCtrlTrafficIn;
+ EDKII_CRYPTO_TLS_READ TlsRead;
+ EDKII_CRYPTO_TLS_WRITE TlsWrite;
/// TLS Set
- EDKII_CRYPTO_TLS_SET_VERSION TlsSetVersion;
- EDKII_CRYPTO_TLS_SET_CONNECTION_END TlsSetConnectionEnd;
- EDKII_CRYPTO_TLS_SET_CIPHER_LIST TlsSetCipherList;
- EDKII_CRYPTO_TLS_SET_COMPRESSION_METHOD TlsSetCompressionMethod;
- EDKII_CRYPTO_TLS_SET_VERIFY TlsSetVerify;
- EDKII_CRYPTO_TLS_SET_VERIFY_HOST TlsSetVerifyHost;
- EDKII_CRYPTO_TLS_SET_SESSIONID TlsSetSessionId;
- EDKII_CRYPTO_TLS_SET_CA_CERTIFICATE TlsSetCaCertificate;
- EDKII_CRYPTO_TLS_SET_HOST_PUBLIC_CERT TlsSetHostPublicCert;
- EDKII_CRYPTO_TLS_SET_HOST_PRIVATE_KEY TlsSetHostPrivateKey;
- EDKII_CRYPTO_TLS_SET_CERT_REVOCATION_LIST TlsSetCertRevocationList;
+ EDKII_CRYPTO_TLS_SET_VERSION TlsSetVersion;
+ EDKII_CRYPTO_TLS_SET_CONNECTION_END TlsSetConnectionEnd;
+ EDKII_CRYPTO_TLS_SET_CIPHER_LIST TlsSetCipherList;
+ EDKII_CRYPTO_TLS_SET_COMPRESSION_METHOD TlsSetCompressionMethod;
+ EDKII_CRYPTO_TLS_SET_VERIFY TlsSetVerify;
+ EDKII_CRYPTO_TLS_SET_VERIFY_HOST TlsSetVerifyHost;
+ EDKII_CRYPTO_TLS_SET_SESSIONID TlsSetSessionId;
+ EDKII_CRYPTO_TLS_SET_CA_CERTIFICATE TlsSetCaCertificate;
+ EDKII_CRYPTO_TLS_SET_HOST_PUBLIC_CERT TlsSetHostPublicCert;
+ EDKII_CRYPTO_TLS_SET_HOST_PRIVATE_KEY TlsSetHostPrivateKey;
+ EDKII_CRYPTO_TLS_SET_CERT_REVOCATION_LIST TlsSetCertRevocationList;
/// TLS Get
- EDKII_CRYPTO_TLS_GET_VERSION TlsGetVersion;
- EDKII_CRYPTO_TLS_GET_CONNECTION_END TlsGetConnectionEnd;
- EDKII_CRYPTO_TLS_GET_CURRENT_CIPHER TlsGetCurrentCipher;
- EDKII_CRYPTO_TLS_GET_CURRENT_COMPRESSION_ID TlsGetCurrentCompressionId;
- EDKII_CRYPTO_TLS_GET_VERIFY TlsGetVerify;
- EDKII_CRYPTO_TLS_GET_SESSION_ID TlsGetSessionId;
- EDKII_CRYPTO_TLS_GET_CLIENT_RANDOM TlsGetClientRandom;
- EDKII_CRYPTO_TLS_GET_SERVER_RANDOM TlsGetServerRandom;
- EDKII_CRYPTO_TLS_GET_KEY_MATERIAL TlsGetKeyMaterial;
- EDKII_CRYPTO_TLS_GET_CA_CERTIFICATE TlsGetCaCertificate;
- EDKII_CRYPTO_TLS_GET_HOST_PUBLIC_CERT TlsGetHostPublicCert;
- EDKII_CRYPTO_TLS_GET_HOST_PRIVATE_KEY TlsGetHostPrivateKey;
- EDKII_CRYPTO_TLS_GET_CERT_REVOCATION_LIST TlsGetCertRevocationList;
+ EDKII_CRYPTO_TLS_GET_VERSION TlsGetVersion;
+ EDKII_CRYPTO_TLS_GET_CONNECTION_END TlsGetConnectionEnd;
+ EDKII_CRYPTO_TLS_GET_CURRENT_CIPHER TlsGetCurrentCipher;
+ EDKII_CRYPTO_TLS_GET_CURRENT_COMPRESSION_ID TlsGetCurrentCompressionId;
+ EDKII_CRYPTO_TLS_GET_VERIFY TlsGetVerify;
+ EDKII_CRYPTO_TLS_GET_SESSION_ID TlsGetSessionId;
+ EDKII_CRYPTO_TLS_GET_CLIENT_RANDOM TlsGetClientRandom;
+ EDKII_CRYPTO_TLS_GET_SERVER_RANDOM TlsGetServerRandom;
+ EDKII_CRYPTO_TLS_GET_KEY_MATERIAL TlsGetKeyMaterial;
+ EDKII_CRYPTO_TLS_GET_CA_CERTIFICATE TlsGetCaCertificate;
+ EDKII_CRYPTO_TLS_GET_HOST_PUBLIC_CERT TlsGetHostPublicCert;
+ EDKII_CRYPTO_TLS_GET_HOST_PRIVATE_KEY TlsGetHostPrivateKey;
+ EDKII_CRYPTO_TLS_GET_CERT_REVOCATION_LIST TlsGetCertRevocationList;
/// RSA PSS
- EDKII_CRYPTO_RSA_PSS_SIGN RsaPssSign;
- EDKII_CRYPTO_RSA_PSS_VERIFY RsaPssVerify;
+ EDKII_CRYPTO_RSA_PSS_SIGN RsaPssSign;
+ EDKII_CRYPTO_RSA_PSS_VERIFY RsaPssVerify;
/// Parallel hash
- EDKII_CRYPTO_PARALLEL_HASH_ALL ParallelHash256HashAll;
+ EDKII_CRYPTO_PARALLEL_HASH_ALL ParallelHash256HashAll;
/// Big Number
- EDKII_CRYPTO_BIGNUM_INIT BigNumInit;
- EDKII_CRYPTO_BIGNUM_FROM_BIN BigNumFromBin;
- EDKII_CRYPTO_BIGNUM_TO_BIN BigNumToBin;
- EDKII_CRYPTO_BIGNUM_FREE BigNumFree;
- EDKII_CRYPTO_BIGNUM_ADD BigNumAdd;
- EDKII_CRYPTO_BIGNUM_SUB BigNumSub;
- EDKII_CRYPTO_BIGNUM_MOD BigNumMod;
- EDKII_CRYPTO_BIGNUM_EXP_MOD BigNumExpMod;
- EDKII_CRYPTO_BIGNUM_INVERSE_MOD BigNumInverseMod;
- EDKII_CRYPTO_BIGNUM_DIV BigNumDiv;
- EDKII_CRYPTO_BIGNUM_MUL_MOD BigNumMulMod;
- EDKII_CRYPTO_BIGNUM_CMP BigNumCmp;
- EDKII_CRYPTO_BIGNUM_BITS BigNumBits;
- EDKII_CRYPTO_BIGNUM_BYTES BigNumBytes;
- EDKII_CRYPTO_BIGNUM_IS_WORD BigNumIsWord;
- EDKII_CRYPTO_BIGNUM_IS_ODD BigNumIsOdd;
- EDKII_CRYPTO_BIGNUM_COPY BigNumCopy;
- EDKII_CRYPTO_BIGNUM_VALUE_ONE BigNumValueOne;
- EDKII_CRYPTO_BIGNUM_R_SHIFT BigNumRShift;
- EDKII_CRYPTO_BIGNUM_CONST_TIME BigNumConstTime;
- EDKII_CRYPTO_BIGNUM_SQR_MOD BigNumSqrMod;
- EDKII_CRYPTO_BIGNUM_NEW_CONTEXT BigNumNewContext;
- EDKII_CRYPTO_BIGNUM_CONTEXT_FREE BigNumContextFree;
- EDKII_CRYPTO_BIGNUM_SET_UINT BigNumSetUint;
- EDKII_CRYPTO_BIGNUM_ADD_MOD BigNumAddMod;
+ EDKII_CRYPTO_BIGNUM_INIT BigNumInit;
+ EDKII_CRYPTO_BIGNUM_FROM_BIN BigNumFromBin;
+ EDKII_CRYPTO_BIGNUM_TO_BIN BigNumToBin;
+ EDKII_CRYPTO_BIGNUM_FREE BigNumFree;
+ EDKII_CRYPTO_BIGNUM_ADD BigNumAdd;
+ EDKII_CRYPTO_BIGNUM_SUB BigNumSub;
+ EDKII_CRYPTO_BIGNUM_MOD BigNumMod;
+ EDKII_CRYPTO_BIGNUM_EXP_MOD BigNumExpMod;
+ EDKII_CRYPTO_BIGNUM_INVERSE_MOD BigNumInverseMod;
+ EDKII_CRYPTO_BIGNUM_DIV BigNumDiv;
+ EDKII_CRYPTO_BIGNUM_MUL_MOD BigNumMulMod;
+ EDKII_CRYPTO_BIGNUM_CMP BigNumCmp;
+ EDKII_CRYPTO_BIGNUM_BITS BigNumBits;
+ EDKII_CRYPTO_BIGNUM_BYTES BigNumBytes;
+ EDKII_CRYPTO_BIGNUM_IS_WORD BigNumIsWord;
+ EDKII_CRYPTO_BIGNUM_IS_ODD BigNumIsOdd;
+ EDKII_CRYPTO_BIGNUM_COPY BigNumCopy;
+ EDKII_CRYPTO_BIGNUM_VALUE_ONE BigNumValueOne;
+ EDKII_CRYPTO_BIGNUM_R_SHIFT BigNumRShift;
+ EDKII_CRYPTO_BIGNUM_CONST_TIME BigNumConstTime;
+ EDKII_CRYPTO_BIGNUM_SQR_MOD BigNumSqrMod;
+ EDKII_CRYPTO_BIGNUM_NEW_CONTEXT BigNumNewContext;
+ EDKII_CRYPTO_BIGNUM_CONTEXT_FREE BigNumContextFree;
+ EDKII_CRYPTO_BIGNUM_SET_UINT BigNumSetUint;
+ EDKII_CRYPTO_BIGNUM_ADD_MOD BigNumAddMod;
/// EC
EDKII_CRYPTO_EC_GROUP_INIT EcGroupInit;
EDKII_CRYPTO_EC_GROUP_GET_CURVE EcGroupGetCurve;
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
index df91752c9c..2636bb6318 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
@@ -11,9 +11,9 @@ SPDX-License-Identifier: BSD-2-Clause-Patent
//
// Debug data
//
-#define MAX_TEST_DATA_SIZE 512
+#define MAX_TEST_DATA_SIZE 512
#define BYTES_OF_OPERATION_A 60
-#define BITS_OF_OPERATION_A 480 //(8 * 60)
+#define BITS_OF_OPERATION_A 480// (8 * 60)
GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnOperationA[] = {
0x00, 0x00, 0x00, 0x00, 0x93, 0x61, 0x7a, 0xba, 0xcc, 0x41, 0x73, 0x49, 0xae, 0x20, 0x41, 0x31,
@@ -88,23 +88,23 @@ GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultExpMod[] = {
// BnOperationA >> 128
GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultRShift[] = {
- 0x93, 0x61, 0x7a, 0xba, 0xcc, 0x41, 0x73, 0x49, 0xae, 0x20, 0x41, 0x31,
- 0x12, 0xe6, 0xfa, 0x4e, 0x89, 0xa9, 0x7e, 0xa2, 0x0a, 0x9e, 0xee, 0xe6, 0x4b, 0x55, 0xd3, 0x9a,
- 0x21, 0x92, 0x99, 0x2a, 0x27, 0x4f, 0xc1, 0xa8, 0x36, 0xba, 0x3c, 0x23, 0xa3, 0xfe, 0xeb, 0xbd
+ 0x93, 0x61, 0x7a, 0xba, 0xcc, 0x41, 0x73, 0x49, 0xae, 0x20, 0x41, 0x31,
+ 0x12, 0xe6, 0xfa, 0x4e, 0x89, 0xa9, 0x7e, 0xa2, 0x0a, 0x9e, 0xee, 0xe6,0x4b, 0x55, 0xd3, 0x9a,
+ 0x21, 0x92, 0x99, 0x2a, 0x27, 0x4f, 0xc1, 0xa8, 0x36, 0xba, 0x3c, 0x23,0xa3, 0xfe, 0xeb, 0xbd
};
// 0x12345678
-GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultUIntSet[] = {0x12, 0x34, 0x56, 0x78};
+GLOBAL_REMOVE_IF_UNREFERENCED CONST UINT8 BnResultUIntSet[] = { 0x12, 0x34, 0x56, 0x78 };
typedef struct {
- VOID *BnA;
- VOID *BnB;
- VOID *BnC;
- VOID *BnD;
- VOID *BnCTX;
+ VOID *BnA;
+ VOID *BnB;
+ VOID *BnC;
+ VOID *BnD;
+ VOID *BnCTX;
} BN_TEST_CONTEXT;
-GLOBAL_REMOVE_IF_UNREFERENCED STATIC BN_TEST_CONTEXT mBnContext = {NULL, NULL, NULL, NULL, NULL};
+GLOBAL_REMOVE_IF_UNREFERENCED STATIC BN_TEST_CONTEXT mBnContext = { NULL, NULL, NULL, NULL, NULL };
//
// Debug function
@@ -112,18 +112,23 @@ GLOBAL_REMOVE_IF_UNREFERENCED STATIC BN_TEST_CONTEXT mBnContext = {NULL, NULL, N
STATIC
BOOLEAN
EqualBn2Bn (
- CONST VOID *Expected, CONST VOID *Actual
+ CONST VOID *Expected,
+ CONST VOID *Actual
)
{
- if (BigNumCmp(Expected, Actual) == 0)
- return TRUE;
- return FALSE;
+ if (BigNumCmp (Expected, Actual) == 0) {
+ return TRUE;
+ }
+
+ return FALSE;
}
STATIC
BOOLEAN
EqualBn2Bin (
- CONST VOID *Bn, CONST UINT8 *Buffer, CONST UINTN BufferSize
+ CONST VOID *Bn,
+ CONST UINT8 *Buffer,
+ CONST UINTN BufferSize
)
{
UINTN BnTestBufferSize;
@@ -135,6 +140,7 @@ EqualBn2Bin (
return TRUE;
}
}
+
return FALSE;
}
@@ -144,22 +150,24 @@ TestVerifyBnPreReq (
UNIT_TEST_CONTEXT Context
)
{
- BN_TEST_CONTEXT *BnContext;
-
- BnContext = Context;
- BnContext->BnCTX = BigNumNewContext();
- BnContext->BnA = BigNumInit();
- BnContext->BnB = BigNumInit();
- BnContext->BnC = BigNumInit();
- BnContext->BnD = BigNumInit();
- if (BnContext->BnCTX == NULL
- || BnContext->BnA == NULL
- || BnContext->BnB == NULL
- || BnContext->BnC == NULL
- || BnContext->BnD == NULL
- ) {
+ BN_TEST_CONTEXT *BnContext;
+
+ BnContext = Context;
+ BnContext->BnCTX = BigNumNewContext ();
+ BnContext->BnA = BigNumInit ();
+ BnContext->BnB = BigNumInit ();
+ BnContext->BnC = BigNumInit ();
+ BnContext->BnD = BigNumInit ();
+ if ( (BnContext->BnCTX == NULL)
+ || (BnContext->BnA == NULL)
+ || (BnContext->BnB == NULL)
+ || (BnContext->BnC == NULL)
+ || (BnContext->BnD == NULL)
+ )
+ {
return UNIT_TEST_ERROR_TEST_FAILED;
}
+
return UNIT_TEST_PASSED;
}
@@ -169,7 +177,7 @@ TestVerifyBnCleanUp (
UNIT_TEST_CONTEXT Context
)
{
- BN_TEST_CONTEXT *BnContext;
+ BN_TEST_CONTEXT *BnContext;
BnContext = Context;
BigNumContextFree (BnContext->BnCTX);
@@ -185,63 +193,64 @@ TestVerifyBn (
IN UNIT_TEST_CONTEXT Context
)
{
- BN_TEST_CONTEXT *BnContext;
- UINTN Num;
- CONST VOID *BnOne;
+ BN_TEST_CONTEXT *BnContext;
+ UINTN Num;
+ CONST VOID *BnOne;
BnContext = Context;
// Calculation tests
BnContext->BnA = BigNumFromBin (BnOperationA, sizeof (BnOperationA));
BnContext->BnB = BigNumFromBin (BnOperationB, sizeof (BnOperationB));
- //C=A+B
+ // C=A+B
BigNumAdd (BnContext->BnA, BnContext->BnB, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultSum, sizeof (BnResultSum)));
- //D=C-A=B
+ // D=C-A=B
BigNumSub (BnContext->BnC, BnContext->BnA, BnContext->BnD);
UT_ASSERT_TRUE (EqualBn2Bn (BnContext->BnB, BnContext->BnD));
- //C=(A+B)%D
+ // C=(A+B)%D
BnContext->BnD = BigNumFromBin (BnOperationMod, sizeof (BnOperationMod));
BigNumAddMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultSumMod, sizeof (BnResultSumMod)));
- //C=(A*B)%D
+ // C=(A*B)%D
BigNumMulMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultMulMod, sizeof (BnResultMulMod)));
- //C=A/D
+ // C=A/D
BigNumDiv (BnContext->BnA, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultDiv, sizeof (BnResultDiv)));
- //C=A%D
+ // C=A%D
BigNumMod (BnContext->BnA, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultMod, sizeof (BnResultMod)));
- //1=(A*C)%D
+ // 1=(A*C)%D
BigNumInverseMod (BnContext->BnA, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultInverseMod, sizeof (BnResultInverseMod)));
- //C=(A^B)%D
+ // C=(A^B)%D
BnContext->BnB = BigNumFromBin (BnOperationExp, sizeof (BnOperationExp));
BigNumExpMod (BnContext->BnA, BnContext->BnB, BnContext->BnD, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultExpMod, sizeof (BnResultExpMod)));
- //C=A>>128
+ // C=A>>128
BigNumRShift (BnContext->BnA, 128, BnContext->BnC);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultRShift, sizeof (BnResultRShift)));
- //C=0x12345678
+ // C=0x12345678
BigNumSetUint (BnContext->BnC, 0x12345678);
UT_ASSERT_TRUE (EqualBn2Bin (BnContext->BnC, BnResultUIntSet, sizeof (BnResultUIntSet)));
- //Bn compare
+ // Bn compare
UT_ASSERT_TRUE (BigNumIsWord (BnContext->BnC, 0x12345678));
UT_ASSERT_FALSE (BigNumIsWord (BnContext->BnC, 0x12345600));
UT_ASSERT_FALSE (BigNumIsOdd (BnContext->BnC));
UT_ASSERT_TRUE (BigNumIsOdd (BnContext->BnA));
- //Other tests
+ // Other tests
BigNumConstTime (BnContext->BnA);
Num = BigNumBytes (BnContext->BnA);
UT_ASSERT_EQUAL (Num, BYTES_OF_OPERATION_A);
Num = BigNumBits (BnContext->BnA);
UT_ASSERT_EQUAL (Num, BITS_OF_OPERATION_A);
- BnOne = BigNumValueOne();
+ BnOne = BigNumValueOne ();
if (BnOne == NULL) {
return UNIT_TEST_ERROR_TEST_FAILED;
}
+
UT_ASSERT_TRUE (BigNumIsWord (BnOne, 0x1));
return UNIT_TEST_PASSED;
@@ -251,7 +260,7 @@ TEST_DESC mBnTest[] = {
//
// -----Description----------------Class---------------------Function-----------Pre----------------Post---------Context
//
- { "TestVerifyBn()", "CryptoPkg.BaseCryptLib.BigNumber", TestVerifyBn, TestVerifyBnPreReq, TestVerifyBnCleanUp, &mBnContext },
+ { "TestVerifyBn()", "CryptoPkg.BaseCryptLib.BigNumber", TestVerifyBn, TestVerifyBnPreReq, TestVerifyBnCleanUp, &mBnContext },
};
-UINTN mBnTestNum = ARRAY_SIZE(mBnTest);
+UINTN mBnTestNum = ARRAY_SIZE (mBnTest);
diff --git a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
index 8008b1dc78..54ce0b22df 100644
--- a/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
+++ b/CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
@@ -8,19 +8,19 @@ SPDX-License-Identifier: BSD-2-Clause-Patent
#include "TestBaseCryptLib.h"
-#define EC_CURVE_NUM_SUPPORTED 3
-UINTN EcCurveList[EC_CURVE_NUM_SUPPORTED] = {CRYPTO_NID_SECP256R1, CRYPTO_NID_SECP384R1, CRYPTO_NID_SECP521R1};
-UINTN EcKeyHalfSize[EC_CURVE_NUM_SUPPORTED] = {32, 48, 66};
+#define EC_CURVE_NUM_SUPPORTED 3
+UINTN EcCurveList[EC_CURVE_NUM_SUPPORTED] = { CRYPTO_NID_SECP256R1, CRYPTO_NID_SECP384R1, CRYPTO_NID_SECP521R1 };
+UINTN EcKeyHalfSize[EC_CURVE_NUM_SUPPORTED] = { 32, 48, 66 };
-struct Generator
-{
- UINT8 X[66];
- UINT8 Y[66];
+struct Generator {
+ UINT8 X[66];
+ UINT8 Y[66];
};
+
// Generator points of all ec curve
-struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
+struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
{
- //CRYPTO_NID_SECP256R1
+ // CRYPTO_NID_SECP256R1
{
{ 0x6B, 0x17, 0xD1, 0xF2, 0xE1, 0x2C, 0x42, 0x47, 0xF8, 0xBC, 0xE6, 0xE5,
0x63, 0xA4, 0x40, 0xF2, 0x77, 0x03, 0x7D, 0x81, 0x2D, 0xEB, 0x33, 0xA0,
@@ -30,7 +30,7 @@ struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
0x7c, 0x0f, 0x9e, 0x16, 0x2b, 0xce, 0x33, 0x57, 0x6b, 0x31, 0x5e, 0xce,
0xcb, 0xb6, 0x40, 0x68, 0x37, 0xbf, 0x51, 0xf5 }
},
- //CRYPTO_NID_SECP384R1
+ // CRYPTO_NID_SECP384R1
{
{ 0xAA, 0x87, 0xCA, 0x22, 0xBE, 0x8B, 0x05, 0x37, 0x8E, 0xB1, 0xC7, 0x1E,
0xF3, 0x20, 0xAD, 0x74, 0x6E, 0x1D, 0x3B, 0x62, 0x8B, 0xA7, 0x9B, 0x98,
@@ -42,7 +42,7 @@ struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
0xe9, 0xda, 0x31, 0x13, 0xb5, 0xf0, 0xb8, 0xc0, 0x0a, 0x60, 0xb1, 0xce,
0x1d, 0x7e, 0x81, 0x9d, 0x7a, 0x43, 0x1d, 0x7c, 0x90, 0xea, 0x0e, 0x5f }
},
- //CRYPTO_NID_SECP521R1
+ // CRYPTO_NID_SECP521R1
{
{ 0x00, 0xC6, 0x85, 0x8E, 0x06, 0xB7, 0x04, 0x04, 0xE9, 0xCD, 0x9E, 0x3E,
0xCB, 0x66, 0x23, 0x95, 0xB4, 0x42, 0x9C, 0x64, 0x81, 0x39, 0x05, 0x3F,
@@ -60,16 +60,16 @@ struct Generator EcCurveGenerator[EC_CURVE_NUM_SUPPORTED] =
}
};
-VOID *Ec1 ;
-VOID *Ec2 ;
-VOID *Group ;
-VOID *Point1 ;
-VOID *Point2 ;
-VOID *PointRes;
-VOID *BnX ;
-VOID *BnY ;
-VOID *BnP ;
-VOID *BnOrder ;
+VOID *Ec1;
+VOID *Ec2;
+VOID *Group;
+VOID *Point1;
+VOID *Point2;
+VOID *PointRes;
+VOID *BnX;
+VOID *BnY;
+VOID *BnP;
+VOID *BnOrder;
UNIT_TEST_STATUS
EFIAPI
@@ -87,9 +87,10 @@ TestVerifyEcPreReq (
BnY = NULL;
BnP = BigNumInit ();
BnOrder = BigNumInit ();
- if (BnP == NULL || BnOrder == NULL) {
+ if ((BnP == NULL) || (BnOrder == NULL)) {
return UNIT_TEST_ERROR_TEST_FAILED;
}
+
return UNIT_TEST_PASSED;
}
@@ -117,8 +118,8 @@ TestVerifyEcBasic (
UNIT_TEST_CONTEXT Context
)
{
- UINTN CurveCount;
- BOOLEAN Status;
+ UINTN CurveCount;
+ BOOLEAN Status;
//
// Initialize BigNumbers
@@ -132,12 +133,12 @@ TestVerifyEcBasic (
return UNIT_TEST_ERROR_TEST_FAILED;
}
- Point1 = EcPointInit (Group);
- Point2 = EcPointInit (Group);
+ Point1 = EcPointInit (Group);
+ Point2 = EcPointInit (Group);
PointRes = EcPointInit (Group);
- BnX = BigNumFromBin (EcCurveGenerator[CurveCount].X, EcKeyHalfSize[CurveCount]);
- BnY = BigNumFromBin (EcCurveGenerator[CurveCount].Y, EcKeyHalfSize[CurveCount]);
- if (Point1 == NULL || Point2 == NULL || PointRes == NULL || BnX == NULL || BnY == NULL) {
+ BnX = BigNumFromBin (EcCurveGenerator[CurveCount].X, EcKeyHalfSize[CurveCount]);
+ BnY = BigNumFromBin (EcCurveGenerator[CurveCount].Y, EcKeyHalfSize[CurveCount]);
+ if ((Point1 == NULL) || (Point2 == NULL) || (PointRes == NULL) || (BnX == NULL) || (BnY == NULL)) {
return UNIT_TEST_ERROR_TEST_FAILED;
}
@@ -147,7 +148,7 @@ TestVerifyEcBasic (
Status = EcGroupGetOrder (Group, BnOrder);
UT_ASSERT_TRUE (Status);
- //Point G should on curve
+ // Point G should on curve
Status = EcPointSetAffineCoordinates (Group, Point1, BnX, BnY, NULL);
UT_ASSERT_TRUE (Status);
@@ -163,21 +164,21 @@ TestVerifyEcBasic (
Status = EcPointIsAtInfinity (Group, Point1);
UT_ASSERT_FALSE (Status);
- //Point 2G should on curve
+ // Point 2G should on curve
Status = EcPointAdd (Group, PointRes, Point1, Point1, NULL);
UT_ASSERT_TRUE (Status);
Status = EcPointIsOnCurve (Group, PointRes, NULL);
UT_ASSERT_TRUE (Status);
- //Point Order * G should at infinity
+ // Point Order * G should at infinity
Status = EcPointMul (Group, PointRes, Point1, BnOrder, NULL);
UT_ASSERT_TRUE (Status);
Status = EcPointIsAtInfinity (Group, PointRes);
UT_ASSERT_TRUE (Status);
- //-(-G) == G
+ // -(-G) == G
Status = EcPointInvert (Group, Point2, NULL);
UT_ASSERT_TRUE (Status);
@@ -190,7 +191,7 @@ TestVerifyEcBasic (
Status = EcPointEqual (Group, Point2, Point1, NULL);
UT_ASSERT_TRUE (Status);
- //Compress point test
+ // Compress point test
Status = EcPointSetCompressedCoordinates (Group, Point1, BnX, 0, NULL);
UT_ASSERT_TRUE (Status);
@@ -216,16 +217,16 @@ TestVerifyEcDh (
UNIT_TEST_CONTEXT Context
)
{
- UINT8 Public1[66 * 2];
- UINTN Public1Length;
- UINT8 Public2[66 * 2];
- UINTN Public2Length;
- UINT8 Key1[66];
- UINTN Key1Length;
- UINT8 Key2[66];
- UINTN Key2Length;
- UINTN CurveCount;
- BOOLEAN Status;
+ UINT8 Public1[66 * 2];
+ UINTN Public1Length;
+ UINT8 Public2[66 * 2];
+ UINTN Public2Length;
+ UINT8 Key1[66];
+ UINTN Key1Length;
+ UINT8 Key2[66];
+ UINTN Key2Length;
+ UINTN CurveCount;
+ BOOLEAN Status;
for (CurveCount = 0; CurveCount < EC_CURVE_NUM_SUPPORTED; CurveCount++) {
//
@@ -233,8 +234,8 @@ TestVerifyEcDh (
//
Public1Length = sizeof (Public1);
Public2Length = sizeof (Public2);
- Key1Length = sizeof (Key1);
- Key2Length = sizeof (Key2);
+ Key1Length = sizeof (Key1);
+ Key2Length = sizeof (Key2);
//
// ECDH functions unit test
//
--
2.31.1.windows.1
^ permalink raw reply related [flat|nested] 11+ messages in thread
* Re: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib
2022-09-07 8:29 [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib yi1 li
` (6 preceding siblings ...)
2022-09-07 8:29 ` [PATCH 7/7] CryptoPkg: Run uncrustify tools on EC and BN change yi1 li
@ 2022-09-20 16:01 ` Yao, Jiewen
2022-09-21 4:56 ` yi1 li
7 siblings, 1 reply; 11+ messages in thread
From: Yao, Jiewen @ 2022-09-20 16:01 UTC (permalink / raw)
To: Li, Yi1, devel@edk2.groups.io; +Cc: Wang, Jian J, Xiaoyu Lu, Jiang, Guomin
Thanks for the patch. Please:
1) Separate BN and EC. Please submit 2 different patch sets. One for EC, the other for BN.
2) Please squash uncrustify tool update into previous patch. No need to submit a standalone one.
3) Please increase EDKII_CRYPTO_VERSION.
With that change, reviewed-by: Jiewen Yao <Jiewen.yao@intel.com>
> -----Original Message-----
> From: Li, Yi1 <yi1.li@intel.com>
> Sent: Wednesday, September 7, 2022 4:29 PM
> To: devel@edk2.groups.io
> Cc: Li, Yi1 <yi1.li@intel.com>; Yao, Jiewen <jiewen.yao@intel.com>; Wang,
> Jian J <jian.j.wang@intel.com>; Xiaoyu Lu <xiaoyux.lu@intel.com>; Jiang,
> Guomin <guomin.jiang@intel.com>
> Subject: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to
> BaseCryptLib
>
> REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
>
> Review PR: https://github.com/tianocore/edk2/pull/3309
> This patch sequence is used to add CryptBn and CryptEc library, which
> are wrapped over OpenSSL. The implementation provides library functions
> for EFI BaseCrypt protocol and EFI BaseCrypt Configuration Protocol.
>
> All APIs passed unit test and fuzzing test, detail as:
> 1. Unit test:
> The purpose of unit testing is to ensure that the function obtains the
> expected result under specific input, that is, to ensure the correctness
> of APIs.
> All test case show in patch 5 and patch 6:
> CryptoPkg/Test: Add unit test for CryptoBn
> CryptoPkg/Test: Add unit test for CryptoEc
> 2. Fuzzing test:
> Various Fuzz Testing are employed across the all introduced APIs, and the
> test is used AFL (2.52b) and Libfuzzer (clang+llvm-11.0.0) as the fuzzer,
> based on HBFA.
> Fuzzing Pass Rate is 100%;
> The Code Coverage of CryptBn is 100%;
> The Code Coverage of CryptEc is 90.3%.
> All test case show in:
> https://github.com/liyi77/edk2-
> staging/tree/HBFA/HBFA/UefiHostFuzzTestCasePkg/TestCase/CryptoPkg
>
> Tested-by: Yi Li <yi1.li@intel.com>
> Cc: Jiewen Yao <jiewen.yao@intel.com>
> Cc: Jian J Wang <jian.j.wang@intel.com>
> Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
> Cc: Guomin Jiang <guomin.jiang@intel.com>
>
> Signed-off-by: Yi Li <yi1.li@intel.com>
>
> Yi Li (7):
> CryptoPkg: Add BigNum support
> CryptoPkg: Add BigNum API to DXE and protocol
> CryptoPkg: Add EC support
> CryptoPkg: Add EC APIs to DXE and protocol
> CryptoPkg/Test: Add unit test for CryptoBn
> CryptoPkg/Test: Add unit test for CryptoEc
> CryptoPkg: Run uncrustify tools on EC and BN change
>
> CryptoPkg/CryptoPkg.dsc | 2 +
> CryptoPkg/Driver/Crypto.c | 1016 +++++++++++++-
> CryptoPkg/Include/Library/BaseCryptLib.h | 842 ++++++++++++
> .../Pcd/PcdCryptoServiceFamilyEnable.h | 55 +
> .../Library/BaseCryptLib/BaseCryptLib.inf | 3 +
> CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c | 581 ++++++++
> .../Library/BaseCryptLib/Bn/CryptBnNull.c | 520 ++++++++
> .../Library/BaseCryptLib/PeiCryptLib.inf | 2 +
> CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c | 765 +++++++++++
> .../Library/BaseCryptLib/Pk/CryptEcNull.c | 496 +++++++
> .../Library/BaseCryptLib/SmmCryptLib.inf | 2 +
> .../BaseCryptLib/UnitTestHostBaseCryptLib.inf | 3 +
> .../BaseCryptLibNull/BaseCryptLibNull.inf | 2 +
> .../Library/BaseCryptLibNull/Bn/CryptBnNull.c | 520 ++++++++
> .../Library/BaseCryptLibNull/Pk/CryptEcNull.c | 496 +++++++
> .../BaseCryptLibOnProtocolPpi/CryptLib.c | 961 ++++++++++++++
> CryptoPkg/Private/Protocol/Crypto.h | 1176 ++++++++++++++---
> CryptoPkg/Test/CryptoPkgHostUnitTest.dsc | 3 +
> .../BaseCryptLib/BaseCryptLibUnitTests.c | 2 +
> .../UnitTest/Library/BaseCryptLib/BnTests.c | 266 ++++
> .../UnitTest/Library/BaseCryptLib/EcTests.c | 290 ++++
> .../Library/BaseCryptLib/TestBaseCryptLib.h | 5 +
> .../BaseCryptLib/TestBaseCryptLibHost.inf | 2 +
> .../BaseCryptLib/TestBaseCryptLibShell.inf | 2 +
> 24 files changed, 7852 insertions(+), 160 deletions(-)
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
> create mode 100644
> CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
> create mode 100644 CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
> create mode 100644
> CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
> create mode 100644
> CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
>
> --
> 2.31.1.windows.1
^ permalink raw reply [flat|nested] 11+ messages in thread
* Re: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib
2022-09-20 16:01 ` [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib Yao, Jiewen
@ 2022-09-21 4:56 ` yi1 li
2022-09-21 10:46 ` Yao, Jiewen
0 siblings, 1 reply; 11+ messages in thread
From: yi1 li @ 2022-09-21 4:56 UTC (permalink / raw)
To: Yao, Jiewen, devel@edk2.groups.io
Cc: Wang, Jian J, Lu, Xiaoyu1, Jiang, Guomin
Hi Jiewen,
Thanks for review, changes done.
Since both BN and EC extend many structures, splitting them will cause git conflicts,
I've adjusted the order of patches: Ec commits are based on Bn commits. Just convenient for merge.
Thanks,
Yi
-----Original Message-----
From: Yao, Jiewen <jiewen.yao@intel.com>
Sent: Wednesday, September 21, 2022 12:02 AM
To: Li, Yi1 <yi1.li@intel.com>; devel@edk2.groups.io
Cc: Wang, Jian J <jian.j.wang@intel.com>; Xiaoyu Lu <xiaoyux.lu@intel.com>; Jiang, Guomin <guomin.jiang@intel.com>
Subject: RE: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib
Thanks for the patch. Please:
1) Separate BN and EC. Please submit 2 different patch sets. One for EC, the other for BN.
2) Please squash uncrustify tool update into previous patch. No need to submit a standalone one.
3) Please increase EDKII_CRYPTO_VERSION.
With that change, reviewed-by: Jiewen Yao <Jiewen.yao@intel.com>
> -----Original Message-----
> From: Li, Yi1 <yi1.li@intel.com>
> Sent: Wednesday, September 7, 2022 4:29 PM
> To: devel@edk2.groups.io
> Cc: Li, Yi1 <yi1.li@intel.com>; Yao, Jiewen <jiewen.yao@intel.com>;
> Wang, Jian J <jian.j.wang@intel.com>; Xiaoyu Lu
> <xiaoyux.lu@intel.com>; Jiang, Guomin <guomin.jiang@intel.com>
> Subject: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to
> BaseCryptLib
>
> REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
>
> Review PR: https://github.com/tianocore/edk2/pull/3309
> This patch sequence is used to add CryptBn and CryptEc library, which
> are wrapped over OpenSSL. The implementation provides library
> functions for EFI BaseCrypt protocol and EFI BaseCrypt Configuration Protocol.
>
> All APIs passed unit test and fuzzing test, detail as:
> 1. Unit test:
> The purpose of unit testing is to ensure that the function obtains the
> expected result under specific input, that is, to ensure the
> correctness of APIs.
> All test case show in patch 5 and patch 6:
> CryptoPkg/Test: Add unit test for CryptoBn
> CryptoPkg/Test: Add unit test for CryptoEc 2. Fuzzing test:
> Various Fuzz Testing are employed across the all introduced APIs, and
> the test is used AFL (2.52b) and Libfuzzer (clang+llvm-11.0.0) as the
> fuzzer, based on HBFA.
> Fuzzing Pass Rate is 100%;
> The Code Coverage of CryptBn is 100%;
> The Code Coverage of CryptEc is 90.3%.
> All test case show in:
> https://github.com/liyi77/edk2-
> staging/tree/HBFA/HBFA/UefiHostFuzzTestCasePkg/TestCase/CryptoPkg
>
> Tested-by: Yi Li <yi1.li@intel.com>
> Cc: Jiewen Yao <jiewen.yao@intel.com>
> Cc: Jian J Wang <jian.j.wang@intel.com>
> Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
> Cc: Guomin Jiang <guomin.jiang@intel.com>
>
> Signed-off-by: Yi Li <yi1.li@intel.com>
>
> Yi Li (7):
> CryptoPkg: Add BigNum support
> CryptoPkg: Add BigNum API to DXE and protocol
> CryptoPkg: Add EC support
> CryptoPkg: Add EC APIs to DXE and protocol
> CryptoPkg/Test: Add unit test for CryptoBn
> CryptoPkg/Test: Add unit test for CryptoEc
> CryptoPkg: Run uncrustify tools on EC and BN change
>
> CryptoPkg/CryptoPkg.dsc | 2 +
> CryptoPkg/Driver/Crypto.c | 1016 +++++++++++++-
> CryptoPkg/Include/Library/BaseCryptLib.h | 842 ++++++++++++
> .../Pcd/PcdCryptoServiceFamilyEnable.h | 55 +
> .../Library/BaseCryptLib/BaseCryptLib.inf | 3 +
> CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c | 581 ++++++++
> .../Library/BaseCryptLib/Bn/CryptBnNull.c | 520 ++++++++
> .../Library/BaseCryptLib/PeiCryptLib.inf | 2 +
> CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c | 765 +++++++++++
> .../Library/BaseCryptLib/Pk/CryptEcNull.c | 496 +++++++
> .../Library/BaseCryptLib/SmmCryptLib.inf | 2 +
> .../BaseCryptLib/UnitTestHostBaseCryptLib.inf | 3 +
> .../BaseCryptLibNull/BaseCryptLibNull.inf | 2 +
> .../Library/BaseCryptLibNull/Bn/CryptBnNull.c | 520 ++++++++
> .../Library/BaseCryptLibNull/Pk/CryptEcNull.c | 496 +++++++
> .../BaseCryptLibOnProtocolPpi/CryptLib.c | 961 ++++++++++++++
> CryptoPkg/Private/Protocol/Crypto.h | 1176 ++++++++++++++---
> CryptoPkg/Test/CryptoPkgHostUnitTest.dsc | 3 +
> .../BaseCryptLib/BaseCryptLibUnitTests.c | 2 +
> .../UnitTest/Library/BaseCryptLib/BnTests.c | 266 ++++
> .../UnitTest/Library/BaseCryptLib/EcTests.c | 290 ++++
> .../Library/BaseCryptLib/TestBaseCryptLib.h | 5 +
> .../BaseCryptLib/TestBaseCryptLibHost.inf | 2 +
> .../BaseCryptLib/TestBaseCryptLibShell.inf | 2 +
> 24 files changed, 7852 insertions(+), 160 deletions(-) create mode
> 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
> create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
> create mode 100644
> CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
> create mode 100644
> CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
> create mode 100644
> CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
> create mode 100644
> CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
>
> --
> 2.31.1.windows.1
^ permalink raw reply [flat|nested] 11+ messages in thread
* Re: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to BaseCryptLib
2022-09-21 4:56 ` yi1 li
@ 2022-09-21 10:46 ` Yao, Jiewen
0 siblings, 0 replies; 11+ messages in thread
From: Yao, Jiewen @ 2022-09-21 10:46 UTC (permalink / raw)
To: Li, Yi1, devel@edk2.groups.io; +Cc: Wang, Jian J, Lu, Xiaoyu1, Jiang, Guomin
Thank you! I will take care of it.
> -----Original Message-----
> From: Li, Yi1 <yi1.li@intel.com>
> Sent: Wednesday, September 21, 2022 12:56 PM
> To: Yao, Jiewen <jiewen.yao@intel.com>; devel@edk2.groups.io
> Cc: Wang, Jian J <jian.j.wang@intel.com>; Lu, Xiaoyu1
> <xiaoyu1.lu@intel.com>; Jiang, Guomin <guomin.jiang@intel.com>
> Subject: RE: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to
> BaseCryptLib
>
> Hi Jiewen,
> Thanks for review, changes done.
> Since both BN and EC extend many structures, splitting them will cause git
> conflicts,
> I've adjusted the order of patches: Ec commits are based on Bn commits.
> Just convenient for merge.
>
> Thanks,
> Yi
> -----Original Message-----
> From: Yao, Jiewen <jiewen.yao@intel.com>
> Sent: Wednesday, September 21, 2022 12:02 AM
> To: Li, Yi1 <yi1.li@intel.com>; devel@edk2.groups.io
> Cc: Wang, Jian J <jian.j.wang@intel.com>; Xiaoyu Lu
> <xiaoyux.lu@intel.com>; Jiang, Guomin <guomin.jiang@intel.com>
> Subject: RE: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to
> BaseCryptLib
>
> Thanks for the patch. Please:
> 1) Separate BN and EC. Please submit 2 different patch sets. One for EC, the
> other for BN.
> 2) Please squash uncrustify tool update into previous patch. No need to
> submit a standalone one.
> 3) Please increase EDKII_CRYPTO_VERSION.
>
> With that change, reviewed-by: Jiewen Yao <Jiewen.yao@intel.com>
>
> > -----Original Message-----
> > From: Li, Yi1 <yi1.li@intel.com>
> > Sent: Wednesday, September 7, 2022 4:29 PM
> > To: devel@edk2.groups.io
> > Cc: Li, Yi1 <yi1.li@intel.com>; Yao, Jiewen <jiewen.yao@intel.com>;
> > Wang, Jian J <jian.j.wang@intel.com>; Xiaoyu Lu
> > <xiaoyux.lu@intel.com>; Jiang, Guomin <guomin.jiang@intel.com>
> > Subject: [PATCH 0/7] CryptoPkg: Add BigNum and EC support to
> > BaseCryptLib
> >
> > REF: https://bugzilla.tianocore.org/show_bug.cgi?id=3828
> >
> > Review PR: https://github.com/tianocore/edk2/pull/3309
> > This patch sequence is used to add CryptBn and CryptEc library, which
> > are wrapped over OpenSSL. The implementation provides library
> > functions for EFI BaseCrypt protocol and EFI BaseCrypt Configuration
> Protocol.
> >
> > All APIs passed unit test and fuzzing test, detail as:
> > 1. Unit test:
> > The purpose of unit testing is to ensure that the function obtains the
> > expected result under specific input, that is, to ensure the
> > correctness of APIs.
> > All test case show in patch 5 and patch 6:
> > CryptoPkg/Test: Add unit test for CryptoBn
> > CryptoPkg/Test: Add unit test for CryptoEc 2. Fuzzing test:
> > Various Fuzz Testing are employed across the all introduced APIs, and
> > the test is used AFL (2.52b) and Libfuzzer (clang+llvm-11.0.0) as the
> > fuzzer, based on HBFA.
> > Fuzzing Pass Rate is 100%;
> > The Code Coverage of CryptBn is 100%;
> > The Code Coverage of CryptEc is 90.3%.
> > All test case show in:
> > https://github.com/liyi77/edk2-
> > staging/tree/HBFA/HBFA/UefiHostFuzzTestCasePkg/TestCase/CryptoPkg
> >
> > Tested-by: Yi Li <yi1.li@intel.com>
> > Cc: Jiewen Yao <jiewen.yao@intel.com>
> > Cc: Jian J Wang <jian.j.wang@intel.com>
> > Cc: Xiaoyu Lu <xiaoyux.lu@intel.com>
> > Cc: Guomin Jiang <guomin.jiang@intel.com>
> >
> > Signed-off-by: Yi Li <yi1.li@intel.com>
> >
> > Yi Li (7):
> > CryptoPkg: Add BigNum support
> > CryptoPkg: Add BigNum API to DXE and protocol
> > CryptoPkg: Add EC support
> > CryptoPkg: Add EC APIs to DXE and protocol
> > CryptoPkg/Test: Add unit test for CryptoBn
> > CryptoPkg/Test: Add unit test for CryptoEc
> > CryptoPkg: Run uncrustify tools on EC and BN change
> >
> > CryptoPkg/CryptoPkg.dsc | 2 +
> > CryptoPkg/Driver/Crypto.c | 1016 +++++++++++++-
> > CryptoPkg/Include/Library/BaseCryptLib.h | 842 ++++++++++++
> > .../Pcd/PcdCryptoServiceFamilyEnable.h | 55 +
> > .../Library/BaseCryptLib/BaseCryptLib.inf | 3 +
> > CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c | 581 ++++++++
> > .../Library/BaseCryptLib/Bn/CryptBnNull.c | 520 ++++++++
> > .../Library/BaseCryptLib/PeiCryptLib.inf | 2 +
> > CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c | 765 +++++++++++
> > .../Library/BaseCryptLib/Pk/CryptEcNull.c | 496 +++++++
> > .../Library/BaseCryptLib/SmmCryptLib.inf | 2 +
> > .../BaseCryptLib/UnitTestHostBaseCryptLib.inf | 3 +
> > .../BaseCryptLibNull/BaseCryptLibNull.inf | 2 +
> > .../Library/BaseCryptLibNull/Bn/CryptBnNull.c | 520 ++++++++
> > .../Library/BaseCryptLibNull/Pk/CryptEcNull.c | 496 +++++++
> > .../BaseCryptLibOnProtocolPpi/CryptLib.c | 961 ++++++++++++++
> > CryptoPkg/Private/Protocol/Crypto.h | 1176 ++++++++++++++---
> > CryptoPkg/Test/CryptoPkgHostUnitTest.dsc | 3 +
> > .../BaseCryptLib/BaseCryptLibUnitTests.c | 2 +
> > .../UnitTest/Library/BaseCryptLib/BnTests.c | 266 ++++
> > .../UnitTest/Library/BaseCryptLib/EcTests.c | 290 ++++
> > .../Library/BaseCryptLib/TestBaseCryptLib.h | 5 +
> > .../BaseCryptLib/TestBaseCryptLibHost.inf | 2 +
> > .../BaseCryptLib/TestBaseCryptLibShell.inf | 2 +
> > 24 files changed, 7852 insertions(+), 160 deletions(-) create mode
> > 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBn.c
> > create mode 100644 CryptoPkg/Library/BaseCryptLib/Bn/CryptBnNull.c
> > create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEc.c
> > create mode 100644 CryptoPkg/Library/BaseCryptLib/Pk/CryptEcNull.c
> > create mode 100644
> > CryptoPkg/Library/BaseCryptLibNull/Bn/CryptBnNull.c
> > create mode 100644
> > CryptoPkg/Library/BaseCryptLibNull/Pk/CryptEcNull.c
> > create mode 100644
> > CryptoPkg/Test/UnitTest/Library/BaseCryptLib/BnTests.c
> > create mode 100644
> > CryptoPkg/Test/UnitTest/Library/BaseCryptLib/EcTests.c
> >
> > --
> > 2.31.1.windows.1
^ permalink raw reply [flat|nested] 11+ messages in thread