Merge pull request #394 from ph4r05/xmr-mg

xmr: MLSAG computation optimized
2024-12-15 19:08:07 +00:00 · 2018-11-02 15:26:48 +01:00 · 2018-11-02 15:26:48 +01:00 · d919e99255
commit d919e99255
parent a2b32115b2 22add1d515
5 changed files with 183 additions and 130 deletions
--- a/src/apps/monero/signing/step_09_sign_input.py
+++ b/src/apps/monero/signing/step_09_sign_input.py
@ -10,7 +10,7 @@ from .state import State
 from apps.monero.layout import confirms
 from apps.monero.signing import RctType
-from apps.monero.xmr import crypto, serialize
+from apps.monero.xmr import crypto
 if False:
    from trezor.messages.MoneroTransactionSourceEntry import (
@ -40,8 +40,6 @@ async def sign_input(
    :param spend_enc: one time address spending private key. Encrypted.
    :return: Generated signature MGs[i]
    """
    from apps.monero.signing import offloading_keys
    await confirms.transaction_step(
        state.ctx, state.STEP_SIGN, state.current_input_index + 1, state.input_count
    )
@ -57,8 +55,11 @@ async def sign_input(
        raise ValueError("Two and more inputs must imply SimpleRCT")
    input_position = state.source_permutation[state.current_input_index]
    mods = utils.unimport_begin()
    # Check input's HMAC
    from apps.monero.signing import offloading_keys
    vini_hmac_comp = await offloading_keys.gen_hmac_vini(
        state.key_hmac, src_entr, vini_bin, input_position
    )
@ -66,7 +67,9 @@ async def sign_input(
        raise ValueError("HMAC is not correct")
    gc.collect()
-    state.mem_trace(1)
+    state.mem_trace(1, True)
    from apps.monero.xmr.crypto import chacha_poly
    if state.rct_type == RctType.Simple:
        # both pseudo_out and its mask were offloaded so we need to
@ -78,10 +81,7 @@ async def sign_input(
        if not crypto.ct_equals(pseudo_out_hmac_comp, pseudo_out_hmac):
            raise ValueError("HMAC is not correct")
-        gc.collect()
+        state.mem_trace(2, True)
        state.mem_trace(2)
        from apps.monero.xmr.crypto import chacha_poly
        pseudo_out_alpha = crypto.decodeint(
            chacha_poly.decrypt_pack(
@ -92,9 +92,6 @@ async def sign_input(
        pseudo_out_c = crypto.decodepoint(pseudo_out)
    # Spending secret
    from apps.monero.xmr.crypto import chacha_poly
    from apps.monero.xmr.serialize_messages.ct_keys import CtKey
    spend_key = crypto.decodeint(
        chacha_poly.decrypt_pack(
            offloading_keys.enc_key_spend(state.key_enc, input_position),
@ -102,8 +99,18 @@ async def sign_input(
        )
    )
-    gc.collect()
+    del (
-    state.mem_trace(3)
+        offloading_keys,
        chacha_poly,
        pseudo_out,
        pseudo_out_hmac,
        pseudo_out_alpha_enc,
        spend_enc,
    )
    utils.unimport_end(mods)
    state.mem_trace(3, True)
    from apps.monero.xmr.serialize_messages.ct_keys import CtKey
    # Basic setup, sanity check
    index = src_entr.real_output
@ -126,14 +133,16 @@ async def sign_input(
        "Real source entry's mask does not equal spend key's",
    )
-    gc.collect()
+    state.mem_trace(4, True)
    state.mem_trace(4)
    from apps.monero.xmr import mlsag
    mg_buffer = []
    ring_pubkeys = [x.key for x in src_entr.outputs]
    del src_entr
    if state.rct_type == RctType.Simple:
-        ring_pubkeys = [x.key for x in src_entr.outputs]
+        mlsag.generate_mlsag_simple(
        mg = mlsag.generate_mlsag_simple(
            state.full_message,
            ring_pubkeys,
            input_secret_key,
@ -141,52 +150,33 @@ async def sign_input(
            pseudo_out_c,
            kLRki,
            index,
            mg_buffer,
        )
        del (input_secret_key, pseudo_out_alpha, pseudo_out_c)
    else:
        # Full RingCt, only one input
        txn_fee_key = crypto.scalarmult_h(state.fee)
-        ring_pubkeys = [[x.key] for x in src_entr.outputs]
+        mlsag.generate_mlsag_full(
        mg = mlsag.generate_mlsag_full(
            state.full_message,
            ring_pubkeys,
-            [input_secret_key],
+            input_secret_key,
            state.output_sk_masks,
            state.output_pk_commitments,
            kLRki,
            index,
            txn_fee_key,
            mg_buffer,
        )
-    gc.collect()
+        del (input_secret_key, txn_fee_key)
    state.mem_trace(5)
-    # Encode
+    del (mlsag, ring_pubkeys)
-    mgs = _recode_msg([mg])
+    state.mem_trace(5, True)
    gc.collect()
    state.mem_trace(6)
    from trezor.messages.MoneroTransactionSignInputAck import (
        MoneroTransactionSignInputAck,
    )
-    return MoneroTransactionSignInputAck(
+    return MoneroTransactionSignInputAck(signature=mg_buffer)
        signature=serialize.dump_msg_gc(mgs[0], preallocate=488)
    )
 def _recode_msg(mgs):
    """
    Recodes MGs signatures from raw forms to bytearrays so it works with serialization
    """
    for idx in range(len(mgs)):
        mgs[idx].cc = crypto.encodeint(mgs[idx].cc)
        if hasattr(mgs[idx], "II") and mgs[idx].II:
            for i in range(len(mgs[idx].II)):
                mgs[idx].II[i] = crypto.encodepoint(mgs[idx].II[i])
        for i in range(len(mgs[idx].ss)):
            for j in range(len(mgs[idx].ss[i])):
                mgs[idx].ss[i][j] = crypto.encodeint(mgs[idx].ss[i][j])
    return mgs
--- a/src/apps/monero/xmr/crypto/init.py
+++ b/src/apps/monero/xmr/crypto/init.py
@ -107,6 +107,7 @@ def sc_init_into(r, x):
    return tcry.init256_modm(r, x)
 sc_copy = tcry.init256_modm
 sc_get64 = tcry.get256_modm
 sc_check = tcry.check256_modm
 check_sc = tcry.check256_modm
--- a/src/apps/monero/xmr/mlsag.py
+++ b/src/apps/monero/xmr/mlsag.py
@ -42,63 +42,76 @@ and `sk` is equal to:
 Mostly ported from official Monero client, but also inspired by Mininero.
 Author: Dusan Klinec, ph4r05, 2018
 """
 import gc
 from apps.monero.xmr import crypto
 from apps.monero.xmr.serialize import int_serialize
 def generate_mlsag_full(
-    message, pubs, in_sk, out_sk_mask, out_pk_commitments, kLRki, index, txn_fee_key
+    message,
    pubs,
    in_sk,
    out_sk_mask,
    out_pk_commitments,
    kLRki,
    index,
    txn_fee_key,
    mg_buff,
 ):
    cols = len(pubs)
    if cols == 0:
        raise ValueError("Empty pubs")
-    rows = len(pubs[0])
+    rows = 1  # Monero uses only one row
    if rows == 0:
        raise ValueError("Empty pub row")
    for i in range(cols):
        if len(pubs[i]) != rows:
            raise ValueError("pub is not rectangular")
    if len(in_sk) != rows:
        raise ValueError("Bad inSk size")
    if len(out_sk_mask) != len(out_pk_commitments):
        raise ValueError("Bad outsk/putpk size")
    sk = _key_vector(rows + 1)
    M = _key_matrix(rows + 1, cols)
-    for i in range(rows + 1):
+
-        sk[i] = crypto.sc_0()
+    tmp_mi_rows = crypto.new_point(None)
    tmp_pt = crypto.new_point(None)
    for i in range(cols):
-        M[i][rows] = crypto.identity()
+        crypto.identity_into(tmp_mi_rows)  # M[i][rows]
        for j in range(rows):
            M[i][j] = crypto.decodepoint(pubs[i][j].dest)
            M[i][rows] = crypto.point_add(
                M[i][rows], crypto.decodepoint(pubs[i][j].commitment)
            )
-    sk[rows] = crypto.sc_0()
+        # Should iterate over rows, simplified as rows == 1
-    for j in range(rows):
+        M[i][0] = pubs[i].dest
-        sk[j] = in_sk[j].dest
+        crypto.point_add_into(
-        sk[rows] = crypto.sc_add(sk[rows], in_sk[j].mask)  # add masks in last row
+            tmp_mi_rows,
            tmp_mi_rows,
            crypto.decodepoint_into(tmp_pt, pubs[i].commitment),
        )
        pubs[i] = None
    for i in range(cols):
        for j in range(len(out_pk_commitments)):
-            M[i][rows] = crypto.point_sub(
+            crypto.point_sub_into(
-                M[i][rows], crypto.decodepoint(out_pk_commitments[j])
+                tmp_mi_rows,
                tmp_mi_rows,
                crypto.decodepoint_into(tmp_pt, out_pk_commitments[j]),
            )  # subtract output Ci's in last row
        # Subtract txn fee output in last row
-        M[i][rows] = crypto.point_sub(M[i][rows], txn_fee_key)
+        crypto.point_sub_into(tmp_mi_rows, tmp_mi_rows, txn_fee_key)
        M[i][rows] = crypto.encodepoint(tmp_mi_rows)
    # Simplified as rows == 1
    sk[0] = in_sk.dest
    sk[rows] = in_sk.mask  # originally: sum of all in_sk[0..rows] in sk[rows]
    for j in range(len(out_pk_commitments)):
-        sk[rows] = crypto.sc_sub(
+        crypto.sc_sub_into(
-            sk[rows], out_sk_mask[j]
+            sk[rows], sk[rows], out_sk_mask[j]
        )  # subtract output masks in last row
-    return generate_mlsag(message, M, sk, kLRki, index, rows)
+    del (pubs, tmp_mi_rows, tmp_pt)
    gc.collect()
    return generate_mlsag(message, M, sk, kLRki, index, rows, mg_buff)
-def generate_mlsag_simple(message, pubs, in_sk, a, cout, kLRki, index):
+def generate_mlsag_simple(message, pubs, in_sk, a, cout, kLRki, index, mg_buff):
    """
    MLSAG for RctType.Simple
    :param message: the full message to be signed (actually its hash)
@ -108,7 +121,7 @@ def generate_mlsag_simple(message, pubs, in_sk, a, cout, kLRki, index):
    :param cout: pseudo output commitment; point, decoded; better name: pseudo_out_c
    :param kLRki: used only in multisig, currently not implemented
    :param index: specifies corresponding public key to the `in_sk` in the pubs array
-    :return: MgSig
+    :param mg_buff: buffer to store the signature to
    """
    # Monero signs inputs separately, so `rows` always equals 2 (pubkey, commitment)
    # and `dsRows` is always 1 (denotes where the pubkeys "end")
@ -123,12 +136,21 @@ def generate_mlsag_simple(message, pubs, in_sk, a, cout, kLRki, index):
    sk[0] = in_sk.dest
    sk[1] = crypto.sc_sub(in_sk.mask, a)
    tmp_pt = crypto.new_point()
    for i in range(cols):
-        M[i][0] = crypto.decodepoint(pubs[i].dest)
+        crypto.point_sub_into(
-        M[i][1] = crypto.point_sub(crypto.decodepoint(pubs[i].commitment), cout)
+            tmp_pt, crypto.decodepoint_into(tmp_pt, pubs[i].commitment), cout
        )
-    return generate_mlsag(message, M, sk, kLRki, index, dsRows)
+        M[i][0] = pubs[i].dest
        M[i][1] = crypto.encodepoint(tmp_pt)
        pubs[i] = None
    del (pubs)
    gc.collect()
    return generate_mlsag(message, M, sk, kLRki, index, dsRows, mg_buff)
 def gen_mlsag_assert(pk, xx, kLRki, index, dsRows):
@ -159,13 +181,10 @@ def gen_mlsag_assert(pk, xx, kLRki, index, dsRows):
    return rows, cols
-def generate_first_c_and_key_images(
+def generate_first_c_and_key_images(message, pk, xx, kLRki, index, dsRows, rows, cols):
    message, rv, pk, xx, kLRki, index, dsRows, rows, cols
 ):
    """
    MLSAG computation - the part with secret keys
    :param message: the full message to be signed (actually its hash)
    :param rv: MgSig
    :param pk: matrix of public keys and commitments
    :param xx: input secret array composed of a private key and commitment mask
    :param kLRki: used only in multisig, currently not implemented
@ -174,18 +193,19 @@ def generate_first_c_and_key_images(
    :param rows: total number of rows
    :param cols: size of ring
    """
-    Ip = _key_vector(dsRows)
+    II = _key_vector(dsRows)
    rv.II = _key_vector(dsRows)
    alpha = _key_vector(rows)
    rv.ss = _key_matrix(rows, cols)
    tmp_buff = bytearray(32)
    Hi = crypto.new_point()
    aGi = crypto.new_point()
    aHPi = crypto.new_point()
    hasher = _hasher_message(message)
    for i in range(dsRows):
        # this is somewhat extra as compared to the Ring Confidential Tx paper
        # see footnote in From Zero to Monero section 3.3
-        hasher.update(crypto.encodepoint(pk[index][i]))
+        hasher.update(pk[index][i])
        if kLRki:
            raise NotImplementedError("Multisig not implemented")
            # alpha[i] = kLRki.k
@ -194,36 +214,34 @@ def generate_first_c_and_key_images(
            # hash_point(hasher, kLRki.R, tmp_buff)
        else:
-            Hi = crypto.hash_to_point(crypto.encodepoint(pk[index][i]))
+            crypto.hash_to_point_into(Hi, pk[index][i])
            alpha[i] = crypto.random_scalar()
            # L = alpha_i * G
-            aGi = crypto.scalarmult_base(alpha[i])
+            crypto.scalarmult_base_into(aGi, alpha[i])
            # Ri = alpha_i * H(P_i)
-            aHPi = crypto.scalarmult(Hi, alpha[i])
+            crypto.scalarmult_into(aHPi, Hi, alpha[i])
            # key image
-            rv.II[i] = crypto.scalarmult(Hi, xx[i])
+            II[i] = crypto.scalarmult(Hi, xx[i])
            _hash_point(hasher, aGi, tmp_buff)
            _hash_point(hasher, aHPi, tmp_buff)
        Ip[i] = rv.II[i]
    for i in range(dsRows, rows):
        alpha[i] = crypto.random_scalar()
        # L = alpha_i * G
-        aGi = crypto.scalarmult_base(alpha[i])
+        crypto.scalarmult_base_into(aGi, alpha[i])
        # for some reasons we omit calculating R here, which seems
        # contrary to the paper, but it is in the Monero official client
        # see https://github.com/monero-project/monero/blob/636153b2050aa0642ba86842c69ac55a5d81618d/src/ringct/rctSigs.cpp#L191
-        _hash_point(hasher, pk[index][i], tmp_buff)
+        hasher.update(pk[index][i])
        _hash_point(hasher, aGi, tmp_buff)
    # the first c
    c_old = hasher.digest()
    c_old = crypto.decodeint(c_old)
-    return c_old, Ip, alpha
+    return c_old, II, alpha
-def generate_mlsag(message, pk, xx, kLRki, index, dsRows):
+def generate_mlsag(message, pk, xx, kLRki, index, dsRows, mg_buff):
    """
    Multilayered Spontaneous Anonymous Group Signatures (MLSAG signatures)
@ -233,56 +251,89 @@ def generate_mlsag(message, pk, xx, kLRki, index, dsRows):
    :param kLRki: used only in multisig, currently not implemented
    :param index: specifies corresponding public key to the `xx`'s private key in the `pk` array
    :param dsRows: separates pubkeys from commitment
-    :return MgSig
+    :param mg_buff: mg signature buffer
    """
    from apps.monero.xmr.serialize_messages.tx_full import MgSig
    rows, cols = gen_mlsag_assert(pk, xx, kLRki, index, dsRows)
    rows_b_size = int_serialize.uvarint_size(rows)
-    rv = MgSig()
+    # Preallocation of the chunked buffer, len + cols + cc
-    c, L, R, Hi = 0, None, None, None
+    for _ in range(1 + cols + 1):
        mg_buff.append(None)
    mg_buff[0] = int_serialize.dump_uvarint_b(cols)
    cc = crypto.new_scalar()  # rv.cc
    c = crypto.new_scalar()
    L = crypto.new_point()
    R = crypto.new_point()
    Hi = crypto.new_point()
    # calculates the "first" c, key images and random scalars alpha
-    c_old, Ip, alpha = generate_first_c_and_key_images(
+    c_old, II, alpha = generate_first_c_and_key_images(
-        message, rv, pk, xx, kLRki, index, dsRows, rows, cols
+        message, pk, xx, kLRki, index, dsRows, rows, cols
    )
    i = (index + 1) % cols
    if i == 0:
-        rv.cc = c_old
+        crypto.sc_copy(cc, c_old)
    ss = [crypto.new_scalar() for _ in range(rows)]
    tmp_buff = bytearray(32)
    while i != index:
        rv.ss[i] = _generate_random_vector(rows)
        hasher = _hasher_message(message)
        # Serialize size of the row
        mg_buff[i + 1] = bytearray(rows_b_size + 32 * rows)
        int_serialize.dump_uvarint_b_into(rows, mg_buff[i + 1])
        for x in ss:
            crypto.random_scalar(x)
        for j in range(dsRows):
            # L = rv.ss[i][j] * G + c_old * pk[i][j]
-            L = crypto.add_keys2(rv.ss[i][j], c_old, pk[i][j])
+            crypto.add_keys2_into(
-            Hi = crypto.hash_to_point(crypto.encodepoint(pk[i][j]))
+                L, ss[j], c_old, crypto.decodepoint_into(Hi, pk[i][j])
            )
            crypto.hash_to_point_into(Hi, pk[i][j])
            # R = rv.ss[i][j] * H(pk[i][j]) + c_old * Ip[j]
-            R = crypto.add_keys3(rv.ss[i][j], Hi, c_old, rv.II[j])
+            crypto.add_keys3_into(R, ss[j], Hi, c_old, II[j])
-            _hash_point(hasher, pk[i][j], tmp_buff)
+
            hasher.update(pk[i][j])
            _hash_point(hasher, L, tmp_buff)
            _hash_point(hasher, R, tmp_buff)
        for j in range(dsRows, rows):
            # again, omitting R here as discussed above
-            L = crypto.add_keys2(rv.ss[i][j], c_old, pk[i][j])
+            crypto.add_keys2_into(
-            _hash_point(hasher, pk[i][j], tmp_buff)
+                L, ss[j], c_old, crypto.decodepoint_into(Hi, pk[i][j])
            )
            hasher.update(pk[i][j])
            _hash_point(hasher, L, tmp_buff)
-        c = crypto.decodeint(hasher.digest())
+        for si in range(rows):
-        c_old = c
+            crypto.encodeint_into(mg_buff[i + 1], ss[si], rows_b_size + 32 * si)
        crypto.decodeint_into(c, hasher.digest())
        crypto.sc_copy(c_old, c)
        pk[i] = None
        i = (i + 1) % cols
        if i == 0:
-            rv.cc = c_old
+            crypto.sc_copy(cc, c_old)
        gc.collect()
    del II
    # Finalizing rv.ss by processing rv.ss[index]
    mg_buff[index + 1] = bytearray(rows_b_size + 32 * rows)
    int_serialize.dump_uvarint_b_into(rows, mg_buff[index + 1])
    for j in range(rows):
-        rv.ss[index][j] = crypto.sc_mulsub(c, xx[j], alpha[j])
+        crypto.sc_mulsub_into(ss[j], c, xx[j], alpha[j])
        crypto.encodeint_into(mg_buff[index + 1], ss[j], rows_b_size + 32 * j)
-    return rv
+    # rv.cc
    mg_buff[-1] = crypto.encodeint(cc)
 def _key_vector(rows):
--- a/src/apps/monero/xmr/serialize_messages/tx_full.py
+++ b/src/apps/monero/xmr/serialize_messages/tx_full.py
@ -1,11 +0,0 @@
 from apps.monero.xmr.serialize.message_types import MessageType
 from apps.monero.xmr.serialize_messages.base import ECKey
 from apps.monero.xmr.serialize_messages.ct_keys import KeyM
 class MgSig(MessageType):
    __slots__ = ("ss", "cc", "II")
    @classmethod
    def f_specs(cls):
        return (("ss", KeyM), ("cc", ECKey))
--- a/src/protobuf.py
+++ b/src/protobuf.py
@ -275,6 +275,11 @@ async def dump_message(writer, msg, fields=None):
            elif ftype is BoolType:
                await dump_uvarint(writer, int(svalue))
            elif ftype is BytesType and is_chunked(svalue):
                await dump_uvarint(writer, len_list_bytes(svalue))
                for sub_svalue in svalue:
                    await writer.awrite(sub_svalue)
            elif ftype is BytesType:
                await dump_uvarint(writer, len(svalue))
                await writer.awrite(svalue)
@ -329,7 +334,9 @@ def count_message(msg, fields=None):
        elif ftype is BytesType:
            for svalue in fvalue:
-                svalue = len(svalue)
+                svalue = (
                    len(svalue) if not is_chunked(svalue) else len_list_bytes(svalue)
                )
                nbytes += count_uvarint(svalue)
                nbytes += svalue
@ -351,3 +358,18 @@ def count_message(msg, fields=None):
            raise TypeError
    return nbytes
 def is_chunked(svalue):
    return (
        isinstance(svalue, list)
        and len(svalue) > 0
        and not isinstance(svalue[0], (int, bool))
    )
 def len_list_bytes(svalue):
    res = 0
    for x in svalue:
        res += len(x)
    return res