#include #include #include #include "buffer.hpp" #include "mem.hpp" struct llarp_async_iwp { struct llarp_alloc *mem; struct llarp_crypto *crypto; struct llarp_logic *logic; struct llarp_threadpool *worker; }; namespace iwp { void inform_keygen(void *user) { iwp_async_keygen *keygen = static_cast< iwp_async_keygen * >(user); keygen->hook(keygen); } void keygen(void *user) { iwp_async_keygen *keygen = static_cast< iwp_async_keygen * >(user); keygen->iwp->crypto->keygen(keygen->keybuf); llarp_thread_job job = {.user = user, .work = &inform_keygen}; llarp_logic_queue_job(keygen->iwp->logic, job); } void inform_gen_intro(void *user) { iwp_async_intro *intro = static_cast< iwp_async_intro * >(user); intro->hook(intro); } void gen_intro(void *user) { iwp_async_intro *intro = static_cast< iwp_async_intro * >(user); llarp_sharedkey_t sharedkey; llarp_shorthash_t e_k; llarp_nonce_t n; llarp_crypto *crypto = intro->iwp->crypto; byte_t tmp[64]; // S = TKE(a.k, b.k, n) printf("dh\n"); crypto->transport_dh_client(sharedkey, intro->remote_pubkey, intro->secretkey, intro->nonce); llarp_buffer_t buf; llarp::StackBuffer< decltype(tmp) >(buf, tmp); // copy nonce memcpy(n, intro->nonce, 24); // e_k = HS(b.k + n) memcpy(tmp, intro->remote_pubkey, 32); memcpy(tmp + 32, intro->nonce, 32); printf("shorthash\n"); crypto->shorthash(e_k, buf); printf("copy\n"); // e = SE(a.k, e_k, n[0:24]) memcpy(intro->buf + 32, llarp_seckey_topublic(intro->secretkey), 32); buf.base = intro->buf + 32; buf.sz = 32; printf("chacha\n"); crypto->xchacha20(buf, e_k, n); // h = MDS( n + e + w0, S) buf.sz = intro->sz - 32; printf("hmac\n"); crypto->hmac(intro->buf, buf, sharedkey); // inform result llarp_logic_queue_job(intro->iwp->logic, {intro, &inform_gen_intro}); } void inform_verify_introack(void *user) { iwp_async_introack *introack = static_cast< iwp_async_introack * >(user); introack->hook(introack); } void verify_introack(void *user) { iwp_async_introack *introack = static_cast< iwp_async_introack * >(user); auto crypto = introack->iwp->crypto; auto logic = introack->iwp->logic; llarp_thread_job job = {.user = user, .work = &inform_verify_introack}; llarp_hmac_t digest; llarp_sharedkey_t sharedkey; auto hmac = introack->buf; auto body = introack->buf + 32; auto pubkey = introack->remote_pubkey; auto secretkey = introack->secretkey; auto nonce = introack->buf + 32; auto token = introack->buf + 64; size_t bodysz = introack->sz - 32; llarp_buffer_t buf; buf.base = body; buf.cur = body; buf.sz = bodysz; // S = TKE(a.k, b.k, n) crypto->transport_dh_client(sharedkey, pubkey, secretkey, nonce); // h = MDS(n + x + w1, S) crypto->hmac(digest, buf, sharedkey); if(!llarp_eq(digest, hmac, 32)) { // fail to verify hmac introack->buf = nullptr; llarp_logic_queue_job(logic, job); return; } buf.base = token; buf.sz = 32; // token = SD(S, x, n[0:24]) crypto->xchacha20(buf, sharedkey, nonce); // copy token memcpy(introack->token, token, 32); llarp_logic_queue_job(logic, job); } void inform_gen_session_start(void *user) { iwp_async_session_start *session = static_cast< iwp_async_session_start * >(user); session->hook(session); } void gen_session_start(void *user) { iwp_async_session_start *session = static_cast< iwp_async_session_start * >(user); auto crypto = session->iwp->crypto; auto dh = crypto->transport_dh_client; auto shorthash = crypto->shorthash; auto hmac = crypto->hmac; auto encrypt = crypto->xchacha20; auto logic = session->iwp->logic; auto a_sK = session->secretkey; auto b_K = session->remote_pubkey; auto N = session->nonce; auto token = session->token; auto K = session->sessionkey; llarp_sharedkey_t e_K; llarp_shorthash_t T; byte_t tmp[64]; llarp_buffer_t buf; llarp::StackBuffer< decltype(tmp) >(buf, tmp); // T = HS(token + n) memcpy(tmp, token, 32); memcpy(tmp + 32, N, 32); shorthash(T, buf); // e_K = TKE(a.k, b.k, N) dh(e_K, b_K, a_sK, N); // K = TKE(a.k, b.k, T) dh(K, b_K, a_sK, T); // x = SE(e_K, token, n[0:24]) buf.base = (session->buf + 32); buf.sz = 32; memcpy(buf.base, token, 32); encrypt(buf, e_K, N); // h = MDS(n + x + w2, e_K) buf.base = (session->buf + 32); buf.sz = session->sz - 32; hmac(session->buf, buf, e_K); // K = TKE(a.k, b.k, T) dh(K, b_K, a_sK, T); llarp_logic_queue_job(logic, {user, &inform_gen_session_start}); } } extern "C" { void iwp_call_async_keygen(struct llarp_async_iwp *iwp, struct iwp_async_keygen *keygen) { keygen->iwp = iwp; llarp_threadpool_queue_job(iwp->worker, {keygen, &iwp::keygen}); } void iwp_call_async_gen_intro(struct llarp_async_iwp *iwp, struct iwp_async_intro *intro) { intro->iwp = iwp; llarp_threadpool_queue_job(iwp->worker, {intro, &iwp::gen_intro}); } void iwp_call_async_verify_introack(struct llarp_async_iwp *iwp, struct iwp_async_introack *introack) { introack->iwp = iwp; llarp_threadpool_queue_job(iwp->worker, {introack, &iwp::verify_introack}); } void iwp_call_async_gen_session_start(struct llarp_async_iwp *iwp, struct iwp_async_session_start *session) { session->iwp = iwp; llarp_threadpool_queue_job(iwp->worker, {session, &iwp::gen_session_start}); } void iwp_call_async_frame_decrypt(struct llarp_async_iwp *iwp, struct iwp_async_frame *frame) { } struct llarp_async_iwp * llarp_async_iwp_new(struct llarp_alloc *mem, struct llarp_crypto *crypto, struct llarp_logic *logic, struct llarp_threadpool *worker) { struct llarp_async_iwp *iwp = llarp::Alloc< llarp_async_iwp >(mem); if(iwp) { iwp->mem = mem; iwp->crypto = crypto; iwp->logic = logic; iwp->worker = worker; } return iwp; } }