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TVM Upgrade 2023.07

подсказка

This upgrade launched run on the Mainnet from December 2023.

c7

c7 is the register in which local context information needed for contract execution (such as time, lt, network configs, etc) is stored.

c7 tuple extended from 10 to 14 elements:

  • 10: cell with code of the smart contract itself.
  • 11: [integer, maybe_dict]: TON value of the incoming message, extracurrency.
  • 12: integer, fees collected in the storage phase.
  • 13: tuple with information about previous blocks.

10 Currently code of the smart contract is presented on TVM level only as executable continuation and can not be transformed to cell. This code is often used to authorize a neighbour contract of the same kind, for instance jetton-wallet authorizes jetton-wallet. For now we need to explicitly store code cell in storage which make storage and init_wrapper more cumbersome than it could be. Using 10 for code is compatible to Everscale update of tvm.

11 Currently value of the incoming message is presented on stack after TVM initiation, so if needed during execution, one either need to store it to global variable or pass through local variables (at funC level it looks like additional msg_value argument in all functions). By putting it to 11 element we will repeat behavior of contract balance: it is presented both on stack and in c7.

12 Currently the only way to calculate storage fees is to store balance in the previous transaction, somehow calculate gas usage in prev transaction and then compare to current balance minus message value. Meanwhile, is often desired to account storage fees.

13 Currently there is no way to retrieve data on previous blocks. One of the kill features of TON is that every structure is a Merkle-proof friendly bag (tree) of cells, moreover TVM is cell and merkle-proof friendly as well. That way, if we include information on the blocks to TVM context it will be possible to make many trustless scenarios: contract A may check transactions on contract B (without B's cooperation), it is possible to recover broken chains of messages (when recover-contract gets and cheks proofs that some transaction occured but reverted), knowing masterchain block hashes is also required to make some validation fisherman functions onchain.

Block ids are presented in the following format:

[ wc:Integer shard:Integer seqno:Integer root_hash:Integer file_hash:Integer ] = BlockId;
[ last_mc_blocks:[BlockId0, BlockId1, ..., BlockId15]
prev_key_block:BlockId ] : PrevBlocksInfo

Ids of the last 16 blocks of masterchain are included (or less if masterchain seqno is less than 16), as well as the last key block. Inclusion of data on shardblocks may cause some data availability issues (due to merge/split events), it is not necessarily required (since any event/data can by proven using masterchain blocks) and thus we decided not to include it.

New opcodes

Rule of thumb when choosing gas cost on new opcodes is that it should not be less than normal (calculated from opcode length) and should take no more than 20 ns per gas unit.

Opcodes to work with new c7 values

26 gas for each, except for PREVMCBLOCKS and PREVKEYBLOCK (34 gas).

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Description
MYCODE- cRetrieves code of smart-contract from c7
INCOMINGVALUE- tRetrieves value of incoming message from c7
STORAGEFEES- iRetrieves value of storage phase fees from c7
PREVBLOCKSINFOTUPLE- tRetrives PrevBlocksInfo: [last_mc_blocks, prev_key_block] from c7
PREVMCBLOCKS- tRetrieves only last_mc_blocks
PREVKEYBLOCK- tRetrieves only prev_key_block
GLOBALID- iRetrieves global_id from 19 network config

Gas

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GASCONSUMED- g_cReturns gas consumed by VM so far (including this instruction).
26 gas

Arithmetics

New variants of the division opcode (A9mscdf) are added: d=0 takes one additional integer from stack and adds it to the intermediate value before division/rshift. These operations return both the quotient and the remainder (just like d=3).

Quiet variants are also available (e.g. QMULADDDIVMOD or QUIET MULADDDIVMOD).

If return values don't fit into 257-bit integers or the divider is zero, non-quiet operation throws an integer overflow exception. Quiet operations return NaN instead of the value that doesn't fit (two NaNs if the divider is zero).

Gas cost is equal to 10 plus opcode length: 26 for most opcodes, +8 for LSHIFT#/RSHIFT#, +8 for quiet.

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MULADDDIVMODx y w z - q=floor((xy+w)/z) r=(xy+w)-zq
MULADDDIVMODRx y w z - q=round((xy+w)/z) r=(xy+w)-zq
MULADDDIVMODCx y w z - q=ceil((xy+w)/z) r=(xy+w)-zq
ADDDIVMODx w z - q=floor((x+w)/z) r=(x+w)-zq
ADDDIVMODRx w z - q=round((x+w)/z) r=(x+w)-zq
ADDDIVMODCx w y - q=ceil((x+w)/z) r=(x+w)-zq
ADDRSHIFTMODx w z - q=floor((x+w)/2^z) r=(x+w)-q*2^z
ADDRSHIFTMODRx w z - q=round((x+w)/2^z) r=(x+w)-q*2^z
ADDRSHIFTMODCx w z - q=ceil((x+w)/2^z) r=(x+w)-q*2^z
z ADDRSHIFT#MODx w - q=floor((x+w)/2^z) r=(x+w)-q*2^z
z ADDRSHIFTR#MODx w - q=round((x+w)/2^z) r=(x+w)-q*2^z
z ADDRSHIFTC#MODx w - q=ceil((x+w)/2^z) r=(x+w)-q*2^z
MULADDRSHIFTMODx y w z - q=floor((xy+w)/2^z) r=(xy+w)-q*2^z
MULADDRSHIFTRMODx y w z - q=round((xy+w)/2^z) r=(xy+w)-q*2^z
MULADDRSHIFTCMODx y w z - q=ceil((xy+w)/2^z) r=(xy+w)-q*2^z
z MULADDRSHIFT#MODx y w - q=floor((xy+w)/2^z) r=(xy+w)-q*2^z
z MULADDRSHIFTR#MODx y w - q=round((xy+w)/2^z) r=(xy+w)-q*2^z
z MULADDRSHIFTC#MODx y w - q=ceil((xy+w)/2^z) r=(xy+w)-q*2^z
LSHIFTADDDIVMODx w z y - q=floor((x*2^y+w)/z) r=(x*2^y+w)-zq
LSHIFTADDDIVMODRx w z y - q=round((x*2^y+w)/z) r=(x*2^y+w)-zq
LSHIFTADDDIVMODCx w z y - q=ceil((x*2^y+w)/z) r=(x*2^y+w)-zq
y LSHIFT#ADDDIVMODx w z - q=floor((x*2^y+w)/z) r=(x*2^y+w)-zq
y LSHIFT#ADDDIVMODRx w z - q=round((x*2^y+w)/z) r=(x*2^y+w)-zq
y LSHIFT#ADDDIVMODCx w z - q=ceil((x*2^y+w)/z) r=(x*2^y+w)-zq

Stack operations

Currently arguments of all stack operations are bounded by 256. That means that if stack become deeper than 256 it becomes difficult to manage deep stack elements. In most cases there are no safety reasons for that limit, i.e. arguments are not limited to prevent too expensive operations. For some mass stack operations, such as ROLLREV (where computation time lineary depends on argument value) gas cost also lineary depends on argument value.

  • Arguments of PICK, ROLL, ROLLREV, BLKSWX, REVX, DROPX, XCHGX, CHKDEPTH, ONLYTOPX, ONLYX are now unlimited.
  • ROLL, ROLLREV, REVX, ONLYTOPX consume more gas when arguments are big: additional gas cost is max(arg-255,0) (for argument less than 256 the gas consumption is constant and corresponds to the current behavior)
  • For BLKSWX, additional cost is max(arg1+arg2-255,0) (this does not correspond to the current behavior, since currently both arg1 and arg2 are limited to 255).

Hashes

Currently only two hash operations are available in TVM: calculation of representation hash of cell/slice, and sha256 of data, but only up to 127 bytes (only that much data fits into one cell).

HASHEXT[A][R]_(HASH) family of operations is added:

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HASHEXT_(HASH)s_1 ... s_n n - hCalculates and returns hash of the concatenation of slices (or builders) s_1...s_n.
HASHEXTR_(HASH)s_n ... s_1 n - hSame thing, but arguments are given in reverse order.
HASHEXTA_(HASH)b s_1 ... s_n n - b'Appends the resulting hash to a builder b instead of pushing it to the stack.
HASHEXTAR_(HASH)b s_n ... s_1 n - b'Arguments are given in reverse order, appends hash to builder.

Only the bits from root cells of s_i are used.

Each chunk s_i may contain non-integer number of bytes. However, the sum of bits of all chunks should be divisible by 8. Note that TON uses most-significant bit ordering, so when two slices with non-integer number of bytes are concatenated, bits from the first slice become most-significant bits.

Gas consumption depends on the number of hashed bytes and the chosen algorithm. Additional 1 gas unit is consumed per chunk.

If [A] is not enabled, the result of hashing will be returned as an unsigned integer if fits 256 bits or tuple of ints otherwise.

The following algorithms are available:

  • SHA256 - openssl implementation, 1/33 gas per byte, hash is 256 bits.
  • SHA512 - openssl implementation, 1/16 gas per byte, hash is 512 bits.
  • BLAKE2B - openssl implementation, 1/19 gas per byte, hash is 512 bits.
  • KECCAK256 - ethereum compatible implementation, 1/11 gas per byte, hash is 256 bits.
  • KECCAK512 - ethereum compatible implementation, 1/6 gas per byte, hash is 512 bits.

Gas usage is rounded down.

Crypto

Currently the only cryptographic algorithm available is CHKSIGN: check the Ed25519-signature of a hash h for a public key k.

  • For compatibility with prev generation blockchains such as Bitcoin and Ethereum we also need checking secp256k1 signatures.
  • For modern cryptographic algorithms the bare minimum is curve addition and multiplication.
  • For compatibility with Ethereum 2.0 PoS and some other modern cryptography we need BLS-signature scheme on bls12-381 curve.
  • For some secure hardware secp256r1 == P256 == prime256v1 is needed.

secp256k1

Bitcoin/ethereum signatures. Uses libsecp256k1 implementation.

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ECRECOVERhash v r s - 0 or h x1 x2 -1Recovers public key from signature, identical to Bitcoin/Ethereum operations.
Takes 32-byte hash as uint256 hash; 65-byte signature as uint8 v and uint256 r, s.
Returns 0 on failure, public key and -1 on success.
65-byte public key is returned as uint8 h, uint256 x1, x2.
1526 gas

secp256r1

Uses OpenSSL implementation. Interface is similar to CHKSIGNS/CHKSIGNU. Compatible with Apple Secure Enclave.

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P256_CHKSIGNSd sig k - ?Checks seck256r1-signature sig of data portion of slice d and public key k. Returns -1 on success, 0 on failure.
Public key is a 33-byte slice (encoded according to Sec. 2.3.4 point 2 of SECG SEC 1).
Signature sig is a 64-byte slice (two 256-bit unsigned integers r and s).
3526 gas
P256_CHKSIGNUh sig k - ?Same thing, but the signed data is 32-byte encoding of 256-bit unsigned integer h.
3526 gas

Ristretto

Extended docs are here. In short, Curve25519 was developed with performance in mind, however it exhibits symmetry due to which group elements have multiple representations. Simpler protocols such as Schnorr signatures or Diffie-Hellman apply tricks at the protocol level to mitigate some issues, but break key derivation and key blinding schemes. And those tricks do not scale to more complex protocols such as Bulletproofs. Ristretto is an arithmetic abstraction over Curve25519 such that each group element corresponds to a unique point, which is the requirement for most cryptographic protocols. Ristretto is essentially a compression/decompression protocol for Curve25519 that offers the required arithmetic abstraction. As a result, crypto protocols are easy to write correctly, while benefiting from the high performance of Curve25519.

Ristretto operations allow calculating curve operations on Curve25519 (the reverse is not true), thus we can consider that we add both Ristretto and Curve25519 curve operation in one step.

libsodium implementation is used.

All ristretto-255 points are represented in TVM as 256-bit unsigned integers. Non-quiet operations throw range_chk if arguments are not valid encoded points. Zero point is represented as integer 0.

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RIST255_FROMHASHh1 h2 - xDeterministically generates a valid point x from a 512-bit hash (given as two 256-bit integers).
626 gas
RIST255_VALIDATEx -Checks that integer x is a valid representation of some curve point. Throws range_chk on error.
226 gas
RIST255_ADDx y - x+yAddition of two points on a curve.
626 gas
RIST255_SUBx y - x-ySubtraction of two points on curve.
626 gas
RIST255_MULx n - x*nMultiplies point x by a scalar n.
Any n is valid, including negative.
2026 gas
RIST255_MULBASEn - g*nMultiplies the generator point g by a scalar n.
Any n is valid, including negative.
776 gas
RIST255_PUSHL- lPushes integer l=2^252+27742317777372353535851937790883648493, which is the order of the group.
26 gas
RIST255_QVALIDATEx - 0 or -1Quiet version of RIST255_VALIDATE.
234 gas
RIST255_QADDx y - 0 or x+y -1Quiet version of RIST255_ADD.
634 gas
RIST255_QSUBx y - 0 or x-y -1Quiet version of RIST255_SUB.
634 gas
RIST255_QMULx n - 0 or x*n -1Quiet version of RIST255_MUL.
2034 gas
RIST255_QMULBASEn - 0 or g*n -1Quiet version of RIST255_MULBASE.
784 gas

BLS12-381

Operations on a pairing friendly BLS12-381 curve. BLST implementation is used. Also, ops for BLS signature scheme which is based on this curve.

BLS values are represented in TVM in the following way:

  • G1-points and public keys: 48-byte slice.
  • G2-points and signatures: 96-byte slice.
  • Elements of field FP: 48-byte slice.
  • Elements of field FP2: 96-byte slice.
  • Messages: slice. Number of bits should be divisible by 8.

When input value is a point or a field element, the slice may have more than 48/96 bytes. In this case only the first 48/96 bytes are taken. If the slice has less bytes (or if message size is not divisible by 8), cell underflow exception is thrown.

High-level operations

These are high-level operations for verifying BLS signatures.

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BLS_VERIFYpk msg sgn - boolChecks BLS signature, return true on success, false otherwise.
61034 gas
BLS_AGGREGATEsig_1 ... sig_n n - sigAggregates signatures. n>0. Throw exception if n=0 or if some sig_i is not a valid signature.
gas=n*4350-2616
BLS_FASTAGGREGATEVERIFY-pk_1 ... pk_n n msg sig - boolChecks aggregated BLS signature for keys pk_1...pk_n and message msg. Return true on success, false otherwise. Return false if n=0.
gas=58034+n*3000
BLS_AGGREGATEVERIFYpk_1 msg_1 ... pk_n msg_n n sgn - boolChecks aggregated BLS signature for key-message pairs pk_1 msg_1...pk_n msg_n. Return true on success, false otherwise. Return false if n=0.
gas=38534+n*22500

VERIFY instructions don't throw exception on invalid signatures and public keys (except for cell underflow exceptions), they return false instead.

Low-level operations

These are arithmetic operations on group elements.

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BLS_G1_ADDx y - x+yAddition on G1.
3934 gas
BLS_G1_SUBx y - x-ySubtraction on G1.
3934 gas
BLS_G1_NEGx - -xNegation on G1.
784 gas
BLS_G1_MULx s - x*sMultiplies G1 point x by scalar s.
Any s is valid, including negative.
5234 gas
BLS_G1_MULTIEXPx_1 s_1 ... x_n s_n n - x_1*s_1+...+x_n*s_nCalculates x_1*s_1+...+x_n*s_n for G1 points x_i and scalars s_i. Returns zero point if n=0.
Any s_i is valid, including negative.
gas=11409+n*630+n/floor(max(log2(n),4))*8820
BLS_G1_ZERO- zeroPushes zero point in G1.
34 gas
BLS_MAP_TO_G1f - xConverts FP element f to a G1 point.
2384 gas
BLS_G1_INGROUPx - boolChecks that slice x represents a valid element of G1.
2984 gas
BLS_G1_ISZEROx - boolChecks that G1 point x is equal to zero.
34 gas
BLS_G2_ADDx y - x+yAddition on G2.
6134 gas
BLS_G2_SUBx y - x-ySubtraction on G2.
6134 gas
BLS_G2_NEGx - -xNegation on G2.
1584 gas
BLS_G2_MULx s - x*sMultiplies G2 point x by scalar s.
Any s is valid, including negative.
10584 gas
BLS_G2_MULTIEXPx_1 s_1 ... x_n s_n n - x_1*s_1+...+x_n*s_nCalculates x_1*s_1+...+x_n*s_n for G2 points x_i and scalars s_i. Returns zero point if n=0.
Any s_i is valid, including negative.
gas=30422+n*1280+n/floor(max(log2(n),4))*22840
BLS_G2_ZERO- zeroPushes zero point in G2.
34 gas
BLS_MAP_TO_G2f - xConverts FP2 element f to a G2 point.
7984 gas
BLS_G2_INGROUPx - boolChecks that slice x represents a valid element of G2.
4284 gas
BLS_G2_ISZEROx - boolChecks that G2 point x is equal to zero.
34 gas
BLS_PAIRINGx_1 y_1 ... x_n y_n n - boolGiven G1 points x_i and G2 points y_i, calculates and multiply pairings of x_i,y_i. Returns true if the result is the multiplicative identity in FP12, false otherwise. Returns false if n=0.
gas=20034+n*11800
BLS_PUSHR- rPushes the order of G1 and G2 (approx. 2^255).
34 gas

INGROUP, ISZERO don't throw exception on invalid points (except for cell underflow exceptions), they return false instead.

Other arithmetic operations throw exception on invalid curve points. Note that they don't check whether given curve points belong to group G1/G2. Use INGROUP instruction to check this.

RUNVM

Currently there is no way for code in TVM to call external untrusted code "in sandbox". In other words, external code always can irreversibly update code, data of contract, or set actions (such as sending all money). RUNVM instruction allows to spawn an independent VM instance, run desired code and get needed data (stack, registers, gas consumption etc) without risks of polluting caller's state. Running arbitrary code in a safe way may be useful for v4-style plugins, Tact's init style subcontract calculation etc.

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flags RUNVMx_1 ... x_n n code [r] [c4] [c7] [g_l] [g_m] - x'_1 ... x'_m exitcode [data'] [c4'] [c5] [g_c]Runs child VM with code code and stack x_1...x_n. Returns the resulting stack x'_1...x'_m and exitcode.
Other arguments and return values are enabled by flags, see below.
RUNVMXx_1 ... x_n n code [r] [c4] [c7] [g_l] [g_m] flags - x'_1 ... x'_m exitcode [data'] [c4'] [c5] [g_c]Same thing, but pops flags from stack.

Flags are similar to runvmx in fift:

  • +1: set c3 to code
  • +2: push an implicit 0 before running the code
  • +4: take c4 from stack (persistent data), return its final value
  • +8: take gas limit g_l from stack, return consumed gas g_c
  • +16: take c7 from stack (smart-contract context)
  • +32: return final value of c5 (actions)
  • +64: pop hard gas limit (enabled by ACCEPT) g_m from stack
  • +128: "isolated gas consumption". Child VM will have a separate set of visited cells and a separate chksgn counter.
  • +256: pop integer r, return exactly r values from the top of the stack (only if exitcode=0 or 1; if not enough then exitcode=stk_und)

Gas cost:

  • 66 gas
  • 1 gas for every stack element given to the child VM (first 32 are free)
  • 1 gas for every stack element returned from the child VM (first 32 are free)

Sending messages

Currently it is difficult to calculate cost of sending message in contract (which leads to some approximations like in jettons) and impossible to bounce request back if action phase is incorrect. It is also impossible to accurately subtract from incoming message sum of "constant fee for contract logic" and "gas expenses".

  • SENDMSG takes a cell and mode as input. Creates an output action and returns a fee for creating a message. Mode has the same effect as in the case of SENDRAWMSG. Additionally +1024 means - do not create an action, only estimate fee. Other modes affect the fee calculation as follows: +64 substitutes the entire balance of the incoming message as an outcoming value (slightly inaccurate, gas expenses that cannot be estimated before the computation is completed are not taken into account), +128 substitutes the value of the entire balance of the contract before the start of the computation phase (slightly inaccurate, since gas expenses that cannot be estimated before the completion of the computation phase are not taken into account).
  • SENDRAWMSG, RAWRESERVE, SETLIBCODE, CHANGELIB - +16 flag is added, that means in the case of action fail - bounce transaction. No effect if +2 is used.