/* This file is part of TALER Copyright (C) 2014, 2015 GNUnet e.V. TALER is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. TALER is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with TALER; see the file COPYING. If not, If not, see */ /** * @file mint/test_mint_api.c * @brief testcase to test mint's HTTP API interface * @author Sree Harsha Totakura * @author Christian Grothoff */ #include "platform.h" #include "taler_util.h" #include "taler_signatures.h" #include "taler_mint_service.h" #include #include /** * Is the configuration file is set to include wire format 'test'? */ #define WIRE_TEST 1 /** * Is the configuration file is set to include wire format 'sepa'? */ #define WIRE_SEPA 1 /** * Main execution context for the main loop. */ static struct TALER_MINT_Context *ctx; /** * Handle to access the mint. */ static struct TALER_MINT_Handle *mint; /** * Task run on shutdown. */ static struct GNUNET_SCHEDULER_Task *shutdown_task; /** * Task that runs the main event loop. */ static struct GNUNET_SCHEDULER_Task *ctx_task; /** * Result of the testcases, #GNUNET_OK on success */ static int result; /** * Opcodes for the interpreter. */ enum OpCode { /** * Termination code, stops the interpreter loop (with success). */ OC_END = 0, /** * Add funds to a reserve by (faking) incoming wire transfer. */ OC_ADMIN_ADD_INCOMING, /** * Check status of a reserve. */ OC_WITHDRAW_STATUS, /** * Withdraw a coin from a reserve. */ OC_WITHDRAW_SIGN, /** * Deposit a coin (pay with it). */ OC_DEPOSIT, /** * Melt a (set of) coins. */ OC_REFRESH_MELT, /** * Complete melting session by withdrawing melted coins. */ OC_REFRESH_REVEAL, /** * Verify mint's /refresh/link by linking original private key to * results from #OC_REFRESH_REVEAL step. */ OC_REFRESH_LINK, /** * Verify the mint's /wire-method. */ OC_WIRE }; /** * Structure specifying details about a coin to be melted. * Used in a NULL-terminated array as part of command * specification. */ struct MeltDetails { /** * Amount to melt (including fee). */ const char *amount; /** * Reference to reserve_withdraw operations for coin to * be used for the /refresh/melt operation. */ const char *coin_ref; }; /** * Information about a fresh coin generated by the refresh operation. */ struct FreshCoin { /** * If @e amount is NULL, this specifies the denomination key to * use. Otherwise, this will be set (by the interpreter) to the * denomination PK matching @e amount. */ const struct TALER_MINT_DenomPublicKey *pk; /** * Set (by the interpreter) to the mint's signature over the * coin's public key. */ struct TALER_DenominationSignature sig; /** * Set (by the interpreter) to the coin's private key. */ struct TALER_CoinSpendPrivateKeyP coin_priv; }; /** * Details for a mint operation to execute. */ struct Command { /** * Opcode of the command. */ enum OpCode oc; /** * Label for the command, can be NULL. */ const char *label; /** * Which response code do we expect for this command? */ unsigned int expected_response_code; /** * Details about the command. */ union { /** * Information for a #OC_ADMIN_ADD_INCOMING command. */ struct { /** * Label to another admin_add_incoming command if we * should deposit into an existing reserve, NULL if * a fresh reserve should be created. */ const char *reserve_reference; /** * String describing the amount to add to the reserve. */ const char *amount; /** * Wire details (JSON). */ const char *wire; /** * Set (by the interpreter) to the reserve's private key * we used to fill the reserve. */ struct TALER_ReservePrivateKeyP reserve_priv; /** * Set to the API's handle during the operation. */ struct TALER_MINT_AdminAddIncomingHandle *aih; } admin_add_incoming; /** * Information for a #OC_WITHDRAW_STATUS command. */ struct { /** * Label to the #OC_ADMIN_ADD_INCOMING command which * created the reserve. */ const char *reserve_reference; /** * Set to the API's handle during the operation. */ struct TALER_MINT_ReserveStatusHandle *wsh; /** * Expected reserve balance. */ const char *expected_balance; } reserve_status; /** * Information for a #OC_WITHDRAW_SIGN command. */ struct { /** * Which reserve should we withdraw from? */ const char *reserve_reference; /** * String describing the denomination value we should withdraw. * A corresponding denomination key must exist in the mint's * offerings. Can be NULL if @e pk is set instead. */ const char *amount; /** * If @e amount is NULL, this specifies the denomination key to * use. Otherwise, this will be set (by the interpreter) to the * denomination PK matching @e amount. */ const struct TALER_MINT_DenomPublicKey *pk; /** * Set (by the interpreter) to the mint's signature over the * coin's public key. */ struct TALER_DenominationSignature sig; /** * Set (by the interpreter) to the coin's private key. */ struct TALER_CoinSpendPrivateKeyP coin_priv; /** * Blinding key used for the operation. */ struct TALER_DenominationBlindingKey blinding_key; /** * Withdraw handle (while operation is running). */ struct TALER_MINT_ReserveWithdrawHandle *wsh; } reserve_withdraw; /** * Information for a #OC_DEPOSIT command. */ struct { /** * Amount to deposit. */ const char *amount; /** * Reference to a reserve_withdraw operation for a coin to * be used for the /deposit operation. */ const char *coin_ref; /** * If this @e coin_ref refers to an operation that generated * an array of coins, this value determines which coin to use. */ unsigned int coin_idx; /** * JSON string describing the merchant's "wire details". */ const char *wire_details; /** * JSON string describing the contract between the two parties. */ const char *contract; /** * Transaction ID to use. */ uint64_t transaction_id; /** * Relative time (to add to 'now') to compute the refund deadline. * Zero for no refunds. */ struct GNUNET_TIME_Relative refund_deadline; /** * Set (by the interpreter) to a fresh private key of the merchant, * if @e refund_deadline is non-zero. */ struct TALER_MerchantPrivateKeyP merchant_priv; /** * Deposit handle while operation is running. */ struct TALER_MINT_DepositHandle *dh; } deposit; /** * Information for a #OC_REFRESH_MELT command. */ struct { /** * Information about coins to be melted. */ struct MeltDetails *melted_coins; /** * Denominations of the fresh coins to withdraw. */ const char **fresh_amounts; /** * Array of the public keys corresponding to * the @e fresh_amounts, set by the interpreter. */ const struct TALER_MINT_DenomPublicKey **fresh_pks; /** * Melt handle while operation is running. */ struct TALER_MINT_RefreshMeltHandle *rmh; /** * Data used in the refresh operation, set by the interpreter. */ char *refresh_data; /** * Number of bytes in @e refresh_data, set by the interpreter. */ size_t refresh_data_length; /** * Set by the interpreter (upon completion) to the noreveal * index selected by the mint. */ uint16_t noreveal_index; } refresh_melt; /** * Information for a #OC_REFRESH_REVEAL command. */ struct { /** * Melt operation this is the matching reveal for. */ const char *melt_ref; /** * Reveal handle while operation is running. */ struct TALER_MINT_RefreshRevealHandle *rrh; /** * Number of fresh coins withdrawn, set by the interpreter. * Length of the @e fresh_coins array. */ unsigned int num_fresh_coins; /** * Information about coins withdrawn, set by the interpreter. */ struct FreshCoin *fresh_coins; } refresh_reveal; /** * Information for a #OC_REFRESH_LINK command. */ struct { /** * Reveal operation this is the matching link for. */ const char *reveal_ref; /** * Link handle while operation is running. */ struct TALER_MINT_RefreshLinkHandle *rlh; /** * Which of the melted coins should be used for the linkage? */ unsigned int coin_idx; } refresh_link; /** * Information for the /wire command. */ struct { /** * Handle to the wire request. */ struct TALER_MINT_WireHandle *wh; /** * Format we expect to see, others will be *ignored*. */ const char *format; } wire; } details; }; /** * State of the interpreter loop. */ struct InterpreterState { /** * Keys from the mint. */ const struct TALER_MINT_Keys *keys; /** * Commands the interpreter will run. */ struct Command *commands; /** * Interpreter task (if one is scheduled). */ struct GNUNET_SCHEDULER_Task *task; /** * Instruction pointer. Tells #interpreter_run() which * instruction to run next. */ unsigned int ip; }; /** * Task that runs the context's event loop with the GNUnet scheduler. * * @param cls unused * @param tc scheduler context (unused) */ static void context_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc); /** * Run the context task, the working set has changed. */ static void trigger_context_task () { GNUNET_SCHEDULER_cancel (ctx_task); ctx_task = GNUNET_SCHEDULER_add_now (&context_task, NULL); } /** * The testcase failed, return with an error code. * * @param is interpreter state to clean up */ static void fail (struct InterpreterState *is) { result = GNUNET_SYSERR; GNUNET_SCHEDULER_shutdown (); } /** * Find a command by label. * * @param is interpreter state to search * @param label label to look for * @return NULL if command was not found */ static const struct Command * find_command (const struct InterpreterState *is, const char *label) { unsigned int i; const struct Command *cmd; if (NULL == label) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Attempt to lookup command for empty label\n"); return NULL; } for (i=0;OC_END != (cmd = &is->commands[i])->oc;i++) if ( (NULL != cmd->label) && (0 == strcmp (cmd->label, label)) ) return cmd; GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command not found: %s\n", label); return NULL; } /** * Run the main interpreter loop that performs mint operations. * * @param cls contains the `struct InterpreterState` * @param tc scheduler context */ static void interpreter_run (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc); /** * Function called upon completion of our /admin/add/incoming request. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful status request * 0 if the mint's reply is bogus (fails to follow the protocol) * @param full_response full response from the mint (for logging, in case of errors) */ static void add_incoming_cb (void *cls, unsigned int http_status, json_t *full_response) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; cmd->details.admin_add_incoming.aih = NULL; if (MHD_HTTP_OK != http_status) { GNUNET_break (0); fail (is); return; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Check if the given historic event @a h corresponds to the given * command @a cmd. * * @param h event in history * @param cmd an #OC_ADMIN_ADD_INCOMING command * @return #GNUNET_OK if they match, #GNUNET_SYSERR if not */ static int compare_admin_add_incoming_history (const struct TALER_MINT_ReserveHistory *h, const struct Command *cmd) { struct TALER_Amount amount; if (TALER_MINT_RTT_DEPOSIT != h->type) { GNUNET_break_op (0); return GNUNET_SYSERR; } GNUNET_assert (GNUNET_OK == TALER_string_to_amount (cmd->details.admin_add_incoming.amount, &amount)); if (0 != TALER_amount_cmp (&amount, &h->amount)) { GNUNET_break_op (0); return GNUNET_SYSERR; } return GNUNET_OK; } /** * Check if the given historic event @a h corresponds to the given * command @a cmd. * * @param h event in history * @param cmd an #OC_WITHDRAW_SIGN command * @return #GNUNET_OK if they match, #GNUNET_SYSERR if not */ static int compare_reserve_withdraw_history (const struct TALER_MINT_ReserveHistory *h, const struct Command *cmd) { struct TALER_Amount amount; struct TALER_Amount amount_with_fee; if (TALER_MINT_RTT_WITHDRAWAL != h->type) { GNUNET_break_op (0); return GNUNET_SYSERR; } GNUNET_assert (GNUNET_OK == TALER_string_to_amount (cmd->details.reserve_withdraw.amount, &amount)); GNUNET_assert (GNUNET_OK == TALER_amount_add (&amount_with_fee, &amount, &cmd->details.reserve_withdraw.pk->fee_withdraw)); if (0 != TALER_amount_cmp (&amount_with_fee, &h->amount)) { GNUNET_break_op (0); return GNUNET_SYSERR; } return GNUNET_OK; } /** * Function called with the result of a /reserve/status request. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful status request * 0 if the mint's reply is bogus (fails to follow the protocol) * @param[in] json original response in JSON format (useful only for diagnostics) * @param balance current balance in the reserve, NULL on error * @param history_length number of entries in the transaction history, 0 on error * @param history detailed transaction history, NULL on error */ static void reserve_status_cb (void *cls, unsigned int http_status, json_t *json, const struct TALER_Amount *balance, unsigned int history_length, const struct TALER_MINT_ReserveHistory *history) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; struct Command *rel; unsigned int i; unsigned int j; struct TALER_Amount amount; cmd->details.reserve_status.wsh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); GNUNET_break (0); json_dumpf (json, stderr, 0); fail (is); return; } switch (http_status) { case MHD_HTTP_OK: /* FIXME: note that history events may come in a different order than the commands. However, for now this works... */ j = 0; for (i=0;iip;i++) { switch ((rel = &is->commands[i])->oc) { case OC_ADMIN_ADD_INCOMING: if ( ( (NULL != rel->label) && (0 == strcmp (cmd->details.reserve_status.reserve_reference, rel->label) ) ) || ( (NULL != rel->details.admin_add_incoming.reserve_reference) && (0 == strcmp (cmd->details.reserve_status.reserve_reference, rel->details.admin_add_incoming.reserve_reference) ) ) ) { if (GNUNET_OK != compare_admin_add_incoming_history (&history[j], rel)) { GNUNET_break (0); fail (is); return; } j++; } break; case OC_WITHDRAW_SIGN: if (0 == strcmp (cmd->details.reserve_status.reserve_reference, rel->details.reserve_withdraw.reserve_reference)) { if (GNUNET_OK != compare_reserve_withdraw_history (&history[j], rel)) { GNUNET_break (0); fail (is); return; } j++; } break; default: /* unreleated, just skip */ break; } } if (j != history_length) { GNUNET_break (0); fail (is); return; } if (NULL != cmd->details.reserve_status.expected_balance) { GNUNET_assert (GNUNET_OK == TALER_string_to_amount (cmd->details.reserve_status.expected_balance, &amount)); if (0 != TALER_amount_cmp (&amount, balance)) { GNUNET_break (0); fail (is); return; } } break; default: /* Unsupported status code (by test harness) */ GNUNET_break (0); break; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function called upon completion of our /reserve/withdraw request. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful status request * 0 if the mint's reply is bogus (fails to follow the protocol) * @param sig signature over the coin, NULL on error * @param full_response full response from the mint (for logging, in case of errors) */ static void reserve_withdraw_cb (void *cls, unsigned int http_status, const struct TALER_DenominationSignature *sig, json_t *full_response) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; cmd->details.reserve_withdraw.wsh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); json_dumpf (full_response, stderr, 0); GNUNET_break (0); fail (is); return; } switch (http_status) { case MHD_HTTP_OK: if (NULL == sig) { GNUNET_break (0); fail (is); return; } cmd->details.reserve_withdraw.sig.rsa_signature = GNUNET_CRYPTO_rsa_signature_dup (sig->rsa_signature); break; case MHD_HTTP_PAYMENT_REQUIRED: /* nothing to check */ break; default: /* Unsupported status code (by test harness) */ GNUNET_break (0); break; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function called with the result of a /deposit operation. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful deposit; * 0 if the mint's reply is bogus (fails to follow the protocol) * @param obj the received JSON reply, should be kept as proof (and, in case of errors, * be forwarded to the customer) */ static void deposit_cb (void *cls, unsigned int http_status, json_t *obj) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; cmd->details.deposit.dh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); json_dumpf (obj, stderr, 0); fail (is); return; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function called with the result of the /refresh/melt operation. * * @param cls closure with the interpreter state * @param http_status HTTP response code, never #MHD_HTTP_OK (200) as for successful intermediate response this callback is skipped. * 0 if the mint's reply is bogus (fails to follow the protocol) * @param noreveal_index choice by the mint in the cut-and-choose protocol, * UINT16_MAX on error * @param full_response full response from the mint (for logging, in case of errors) */ static void melt_cb (void *cls, unsigned int http_status, uint16_t noreveal_index, json_t *full_response) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; cmd->details.refresh_melt.rmh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); json_dumpf (full_response, stderr, 0); fail (is); return; } cmd->details.refresh_melt.noreveal_index = noreveal_index; is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function called with the result of the /refresh/reveal operation. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful status request * 0 if the mint's reply is bogus (fails to follow the protocol) * @param num_coins number of fresh coins created, length of the @a sigs and @a coin_privs arrays, 0 if the operation failed * @param coin_privs array of @a num_coins private keys for the coins that were created, NULL on error * @param sigs array of signature over @a num_coins coins, NULL on error * @param full_response full response from the mint (for logging, in case of errors) */ static void reveal_cb (void *cls, unsigned int http_status, unsigned int num_coins, const struct TALER_CoinSpendPrivateKeyP *coin_privs, const struct TALER_DenominationSignature *sigs, json_t *full_response) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; const struct Command *ref; unsigned int i; cmd->details.refresh_reveal.rrh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); json_dumpf (full_response, stderr, 0); fail (is); return; } ref = find_command (is, cmd->details.refresh_reveal.melt_ref); cmd->details.refresh_reveal.num_fresh_coins = num_coins; switch (http_status) { case MHD_HTTP_OK: cmd->details.refresh_reveal.fresh_coins = GNUNET_new_array (num_coins, struct FreshCoin); for (i=0;idetails.refresh_reveal.fresh_coins[i]; fc->pk = ref->details.refresh_melt.fresh_pks[i]; fc->coin_priv = coin_privs[i]; fc->sig.rsa_signature = GNUNET_CRYPTO_rsa_signature_dup (sigs[i].rsa_signature); } break; default: break; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function called with the result of a /refresh/link operation. * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful status request * 0 if the mint's reply is bogus (fails to follow the protocol) * @param num_coins number of fresh coins created, length of the @a sigs and @a coin_privs arrays, 0 if the operation failed * @param coin_privs array of @a num_coins private keys for the coins that were created, NULL on error * @param sigs array of signature over @a num_coins coins, NULL on error * @param pubs array of public keys for the @a sigs, NULL on error * @param full_response full response from the mint (for logging, in case of errors) */ static void link_cb (void *cls, unsigned int http_status, unsigned int num_coins, const struct TALER_CoinSpendPrivateKeyP *coin_privs, const struct TALER_DenominationSignature *sigs, const struct TALER_DenominationPublicKey *pubs, json_t *full_response) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; const struct Command *ref; unsigned int i; unsigned int j; unsigned int found; cmd->details.refresh_link.rlh = NULL; if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s\n", http_status, cmd->label); json_dumpf (full_response, stderr, 0); fail (is); return; } ref = find_command (is, cmd->details.refresh_link.reveal_ref); switch (http_status) { case MHD_HTTP_OK: /* check that number of coins returned matches */ if (num_coins != ref->details.refresh_reveal.num_fresh_coins) { GNUNET_break (0); fail (is); return; } /* check that the coins match */ for (i=0;idetails.refresh_reveal.fresh_coins[j]; if ( (0 == memcmp (&coin_privs[i], &fc->coin_priv, sizeof (struct TALER_CoinSpendPrivateKeyP))) && (0 == GNUNET_CRYPTO_rsa_signature_cmp (fc->sig.rsa_signature, sigs[i].rsa_signature)) && (0 == GNUNET_CRYPTO_rsa_public_key_cmp (fc->pk->key.rsa_public_key, pubs[i].rsa_public_key)) ) { found++; break; } } if (found != num_coins) { fprintf (stderr, "Only %u/%u coins match expectations\n", found, num_coins); GNUNET_break (0); fail (is); return; } break; default: break; } is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Find denomination key matching the given amount. * * @param keys array of keys to search * @param amount coin value to look for * @return NULL if no matching key was found */ static const struct TALER_MINT_DenomPublicKey * find_pk (const struct TALER_MINT_Keys *keys, const struct TALER_Amount *amount) { unsigned int i; struct GNUNET_TIME_Absolute now; struct TALER_MINT_DenomPublicKey *pk; char *str; now = GNUNET_TIME_absolute_get (); for (i=0;inum_denom_keys;i++) { pk = &keys->denom_keys[i]; if ( (0 == TALER_amount_cmp (amount, &pk->value)) && (now.abs_value_us >= pk->valid_from.abs_value_us) && (now.abs_value_us < pk->withdraw_valid_until.abs_value_us) ) return pk; } /* do 2nd pass to check if expiration times are to blame for failure */ str = TALER_amount_to_string (amount); for (i=0;inum_denom_keys;i++) { pk = &keys->denom_keys[i]; if ( (0 == TALER_amount_cmp (amount, &pk->value)) && ( (now.abs_value_us < pk->valid_from.abs_value_us) || (now.abs_value_us > pk->withdraw_valid_until.abs_value_us) ) ) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Have denomination key for `%s', but with wrong expiration range %llu vs [%llu,%llu)\n", str, now.abs_value_us, pk->valid_from.abs_value_us, pk->withdraw_valid_until.abs_value_us); GNUNET_free (str); return NULL; } } GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "No denomination key for amount %s found\n", str); GNUNET_free (str); return NULL; } /** * Callbacks called with the result(s) of a * wire format inquiry request to the mint. * * The callback is invoked multiple times, once for each supported @a * method. Finally, it is invoked one more time with cls/0/NULL/NULL * to indicate the end of the iteration. If any request fails to * generate a valid response from the mint, @a http_status will also * be zero and the iteration will also end. Thus, the iteration * always ends with a final call with an @a http_status of 0. If the * @a http_status is already 0 on the first call, then the response to * the /wire request was invalid. Later, clients can tell the * difference between @a http_status of 0 indicating a failed * /wire/method request and a regular end of the iteration by @a * method being non-NULL. If the mint simply correctly asserts that * it does not support any methods, @a method will be NULL but the @a * http_status will be #MHD_HTTP_OK for the first call (followed by a * cls/0/NULL/NULL call to signal the end of the iteration). * * @param cls closure with the interpreter state * @param http_status HTTP response code, #MHD_HTTP_OK (200) for successful request; * 0 if the mint's reply is bogus (fails to follow the protocol) * @param method wire format method supported, i.e. "test" or "sepa", or NULL * if already the /wire request failed. * @param obj the received JSON reply, if successful this should be the wire * format details as provided by /wire/METHOD/, or NULL if the * reply was not in JSON format (in this case, the client might * want to do an HTTP request to /wire/METHOD/ with a browser to * provide more information to the user about the @a method). */ static void wire_cb (void *cls, unsigned int http_status, const char *method, json_t *obj) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; if (0 == http_status) { /* 0 always signals the end of the iteration */ cmd->details.wire.wh = NULL; } else if ( (NULL != method) && (0 != strcasecmp (method, cmd->details.wire.format)) ) { /* not the method we care about, skip */ return; } if (cmd->expected_response_code != http_status) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unexpected response code %u to command %s/%s\n", http_status, cmd->label, method); json_dumpf (obj, stderr, 0); fail (is); return; } if (0 == http_status) { /* end of iteration, move to next command */ is->ip++; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); return; } /* For now, we only support to be called only once with a "positive" result; so we switch to an expected value of 0 for the 2nd iteration */ cmd->expected_response_code = 0; } /** * Run the main interpreter loop that performs mint operations. * * @param cls contains the `struct InterpreterState` * @param tc scheduler context */ static void interpreter_run (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct InterpreterState *is = cls; struct Command *cmd = &is->commands[is->ip]; const struct Command *ref; struct TALER_ReservePublicKeyP reserve_pub; struct TALER_CoinSpendPublicKeyP coin_pub; struct TALER_Amount amount; struct GNUNET_TIME_Absolute execution_date; json_t *wire; is->task = NULL; if (0 != (tc->reason & GNUNET_SCHEDULER_REASON_SHUTDOWN)) { fprintf (stderr, "Test aborted by shutdown request\n"); fail (is); return; } switch (cmd->oc) { case OC_END: result = GNUNET_OK; GNUNET_SCHEDULER_shutdown (); return; case OC_ADMIN_ADD_INCOMING: if (NULL != cmd->details.admin_add_incoming.reserve_reference) { ref = find_command (is, cmd->details.admin_add_incoming.reserve_reference); GNUNET_assert (NULL != ref); GNUNET_assert (OC_ADMIN_ADD_INCOMING == ref->oc); cmd->details.admin_add_incoming.reserve_priv = ref->details.admin_add_incoming.reserve_priv; } else { struct GNUNET_CRYPTO_EddsaPrivateKey *priv; priv = GNUNET_CRYPTO_eddsa_key_create (); cmd->details.admin_add_incoming.reserve_priv.eddsa_priv = *priv; GNUNET_free (priv); } GNUNET_CRYPTO_eddsa_key_get_public (&cmd->details.admin_add_incoming.reserve_priv.eddsa_priv, &reserve_pub.eddsa_pub); if (GNUNET_OK != TALER_string_to_amount (cmd->details.admin_add_incoming.amount, &amount)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse amount `%s' at %u\n", cmd->details.admin_add_incoming.amount, is->ip); fail (is); return; } wire = json_loads (cmd->details.admin_add_incoming.wire, JSON_REJECT_DUPLICATES, NULL); if (NULL == wire) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse wire details `%s' at %u\n", cmd->details.admin_add_incoming.wire, is->ip); fail (is); return; } execution_date = GNUNET_TIME_absolute_get (); TALER_round_abs_time (&execution_date); cmd->details.admin_add_incoming.aih = TALER_MINT_admin_add_incoming (mint, &reserve_pub, &amount, execution_date, wire, &add_incoming_cb, is); if (NULL == cmd->details.admin_add_incoming.aih) { GNUNET_break (0); fail (is); return; } trigger_context_task (); return; case OC_WITHDRAW_STATUS: GNUNET_assert (NULL != cmd->details.reserve_status.reserve_reference); ref = find_command (is, cmd->details.reserve_status.reserve_reference); GNUNET_assert (NULL != ref); GNUNET_assert (OC_ADMIN_ADD_INCOMING == ref->oc); GNUNET_CRYPTO_eddsa_key_get_public (&ref->details.admin_add_incoming.reserve_priv.eddsa_priv, &reserve_pub.eddsa_pub); cmd->details.reserve_status.wsh = TALER_MINT_reserve_status (mint, &reserve_pub, &reserve_status_cb, is); trigger_context_task (); return; case OC_WITHDRAW_SIGN: GNUNET_assert (NULL != cmd->details.reserve_withdraw.reserve_reference); ref = find_command (is, cmd->details.reserve_withdraw.reserve_reference); GNUNET_assert (NULL != ref); GNUNET_assert (OC_ADMIN_ADD_INCOMING == ref->oc); if (NULL != cmd->details.reserve_withdraw.amount) { if (GNUNET_OK != TALER_string_to_amount (cmd->details.reserve_withdraw.amount, &amount)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse amount `%s' at %u\n", cmd->details.reserve_withdraw.amount, is->ip); fail (is); return; } cmd->details.reserve_withdraw.pk = find_pk (is->keys, &amount); } if (NULL == cmd->details.reserve_withdraw.pk) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to determine denomination key at %u\n", is->ip); fail (is); return; } /* create coin's private key */ { struct GNUNET_CRYPTO_EddsaPrivateKey *priv; priv = GNUNET_CRYPTO_eddsa_key_create (); cmd->details.reserve_withdraw.coin_priv.eddsa_priv = *priv; GNUNET_free (priv); } GNUNET_CRYPTO_eddsa_key_get_public (&cmd->details.reserve_withdraw.coin_priv.eddsa_priv, &coin_pub.eddsa_pub); cmd->details.reserve_withdraw.blinding_key.rsa_blinding_key = GNUNET_CRYPTO_rsa_blinding_key_create (GNUNET_CRYPTO_rsa_public_key_len (cmd->details.reserve_withdraw.pk->key.rsa_public_key)); cmd->details.reserve_withdraw.wsh = TALER_MINT_reserve_withdraw (mint, cmd->details.reserve_withdraw.pk, &ref->details.admin_add_incoming.reserve_priv, &cmd->details.reserve_withdraw.coin_priv, &cmd->details.reserve_withdraw.blinding_key, &reserve_withdraw_cb, is); if (NULL == cmd->details.reserve_withdraw.wsh) { GNUNET_break (0); fail (is); return; } trigger_context_task (); return; case OC_DEPOSIT: { struct GNUNET_HashCode h_contract; const struct TALER_CoinSpendPrivateKeyP *coin_priv; const struct TALER_MINT_DenomPublicKey *coin_pk; const struct TALER_DenominationSignature *coin_pk_sig; struct TALER_CoinSpendPublicKeyP coin_pub; struct TALER_CoinSpendSignatureP coin_sig; struct GNUNET_TIME_Absolute refund_deadline; struct GNUNET_TIME_Absolute wire_deadline; struct GNUNET_TIME_Absolute timestamp; struct TALER_MerchantPublicKeyP merchant_pub; json_t *wire; GNUNET_assert (NULL != cmd->details.deposit.coin_ref); ref = find_command (is, cmd->details.deposit.coin_ref); GNUNET_assert (NULL != ref); switch (ref->oc) { case OC_WITHDRAW_SIGN: coin_priv = &ref->details.reserve_withdraw.coin_priv; coin_pk = ref->details.reserve_withdraw.pk; coin_pk_sig = &ref->details.reserve_withdraw.sig; break; case OC_REFRESH_REVEAL: { const struct FreshCoin *fc; unsigned int idx; idx = cmd->details.deposit.coin_idx; GNUNET_assert (idx < ref->details.refresh_reveal.num_fresh_coins); fc = &ref->details.refresh_reveal.fresh_coins[idx]; coin_priv = &fc->coin_priv; coin_pk = fc->pk; coin_pk_sig = &fc->sig; } break; default: GNUNET_assert (0); } if (GNUNET_OK != TALER_string_to_amount (cmd->details.deposit.amount, &amount)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse amount `%s' at %u\n", cmd->details.deposit.amount, is->ip); fail (is); return; } GNUNET_CRYPTO_hash (cmd->details.deposit.contract, strlen (cmd->details.deposit.contract), &h_contract); wire = json_loads (cmd->details.deposit.wire_details, JSON_REJECT_DUPLICATES, NULL); if (NULL == wire) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse wire details `%s' at %u\n", cmd->details.deposit.wire_details, is->ip); fail (is); return; } GNUNET_CRYPTO_eddsa_key_get_public (&coin_priv->eddsa_priv, &coin_pub.eddsa_pub); if (0 != cmd->details.deposit.refund_deadline.rel_value_us) { struct GNUNET_CRYPTO_EddsaPrivateKey *priv; priv = GNUNET_CRYPTO_eddsa_key_create (); cmd->details.deposit.merchant_priv.eddsa_priv = *priv; GNUNET_free (priv); refund_deadline = GNUNET_TIME_relative_to_absolute (cmd->details.deposit.refund_deadline); } else { refund_deadline = GNUNET_TIME_UNIT_ZERO_ABS; } wire_deadline = GNUNET_TIME_relative_to_absolute (GNUNET_TIME_UNIT_DAYS); timestamp = GNUNET_TIME_absolute_get (); TALER_round_abs_time (×tamp); { struct TALER_DepositRequestPS dr; memset (&dr, 0, sizeof (dr)); dr.purpose.size = htonl (sizeof (struct TALER_DepositRequestPS)); dr.purpose.purpose = htonl (TALER_SIGNATURE_WALLET_COIN_DEPOSIT); dr.h_contract = h_contract; TALER_hash_json (wire, &dr.h_wire); dr.timestamp = GNUNET_TIME_absolute_hton (timestamp); dr.refund_deadline = GNUNET_TIME_absolute_hton (refund_deadline); dr.transaction_id = GNUNET_htonll (cmd->details.deposit.transaction_id); TALER_amount_hton (&dr.amount_with_fee, &amount); TALER_amount_hton (&dr.deposit_fee, &coin_pk->fee_deposit); dr.merchant = merchant_pub; dr.coin_pub = coin_pub; GNUNET_assert (GNUNET_OK == GNUNET_CRYPTO_eddsa_sign (&coin_priv->eddsa_priv, &dr.purpose, &coin_sig.eddsa_signature)); } cmd->details.deposit.dh = TALER_MINT_deposit (mint, &amount, wire_deadline, wire, &h_contract, &coin_pub, coin_pk_sig, &coin_pk->key, timestamp, cmd->details.deposit.transaction_id, &merchant_pub, refund_deadline, &coin_sig, &deposit_cb, is); if (NULL == cmd->details.deposit.dh) { GNUNET_break (0); json_decref (wire); fail (is); return; } json_decref (wire); trigger_context_task (); return; } case OC_REFRESH_MELT: { unsigned int num_melted_coins; unsigned int num_fresh_coins; cmd->details.refresh_melt.noreveal_index = UINT16_MAX; for (num_melted_coins=0; NULL != cmd->details.refresh_melt.melted_coins[num_melted_coins].amount; num_melted_coins++) ; for (num_fresh_coins=0; NULL != cmd->details.refresh_melt.fresh_amounts[num_fresh_coins]; num_fresh_coins++) ; cmd->details.refresh_melt.fresh_pks = GNUNET_new_array (num_fresh_coins, const struct TALER_MINT_DenomPublicKey *); { struct TALER_CoinSpendPrivateKeyP melt_privs[num_melted_coins]; struct TALER_Amount melt_amounts[num_melted_coins]; struct TALER_DenominationSignature melt_sigs[num_melted_coins]; struct TALER_MINT_DenomPublicKey melt_pks[num_melted_coins]; struct TALER_MINT_DenomPublicKey fresh_pks[num_fresh_coins]; unsigned int i; for (i=0;idetails.refresh_melt.melted_coins[i]; ref = find_command (is, md->coin_ref); GNUNET_assert (NULL != ref); GNUNET_assert (OC_WITHDRAW_SIGN == ref->oc); melt_privs[i] = ref->details.reserve_withdraw.coin_priv; if (GNUNET_OK != TALER_string_to_amount (md->amount, &melt_amounts[i])) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse amount `%s' at %u\n", md->amount, is->ip); fail (is); return; } melt_sigs[i] = ref->details.reserve_withdraw.sig; melt_pks[i] = *ref->details.reserve_withdraw.pk; } for (i=0;idetails.refresh_melt.fresh_amounts[i], &amount)) { GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Failed to parse amount `%s' at %u\n", cmd->details.reserve_withdraw.amount, is->ip); fail (is); return; } cmd->details.refresh_melt.fresh_pks[i] = find_pk (is->keys, &amount); fresh_pks[i] = *cmd->details.refresh_melt.fresh_pks[i]; } cmd->details.refresh_melt.refresh_data = TALER_MINT_refresh_prepare (num_melted_coins, melt_privs, melt_amounts, melt_sigs, melt_pks, GNUNET_YES, num_fresh_coins, fresh_pks, &cmd->details.refresh_melt.refresh_data_length); if (NULL == cmd->details.refresh_melt.refresh_data) { GNUNET_break (0); fail (is); return; } cmd->details.refresh_melt.rmh = TALER_MINT_refresh_melt (mint, cmd->details.refresh_melt.refresh_data_length, cmd->details.refresh_melt.refresh_data, &melt_cb, is); if (NULL == cmd->details.refresh_melt.rmh) { GNUNET_break (0); fail (is); return; } } } trigger_context_task (); return; case OC_REFRESH_REVEAL: ref = find_command (is, cmd->details.refresh_reveal.melt_ref); cmd->details.refresh_reveal.rrh = TALER_MINT_refresh_reveal (mint, ref->details.refresh_melt.refresh_data_length, ref->details.refresh_melt.refresh_data, ref->details.refresh_melt.noreveal_index, &reveal_cb, is); if (NULL == cmd->details.refresh_reveal.rrh) { GNUNET_break (0); fail (is); return; } trigger_context_task (); return; case OC_REFRESH_LINK: /* find reveal command */ ref = find_command (is, cmd->details.refresh_link.reveal_ref); /* find melt command */ ref = find_command (is, ref->details.refresh_reveal.melt_ref); /* find reserve_withdraw command */ { unsigned int idx; const struct MeltDetails *md; unsigned int num_melted_coins; for (num_melted_coins=0; NULL != ref->details.refresh_melt.melted_coins[num_melted_coins].amount; num_melted_coins++) ; idx = cmd->details.refresh_link.coin_idx; GNUNET_assert (idx < num_melted_coins); md = &ref->details.refresh_melt.melted_coins[idx]; ref = find_command (is, md->coin_ref); } GNUNET_assert (OC_WITHDRAW_SIGN == ref->oc); /* finally, use private key from withdraw sign command */ cmd->details.refresh_link.rlh = TALER_MINT_refresh_link (mint, &ref->details.reserve_withdraw.coin_priv, &link_cb, is); if (NULL == cmd->details.refresh_link.rlh) { GNUNET_break (0); fail (is); return; } trigger_context_task (); return; case OC_WIRE: cmd->details.wire.wh = TALER_MINT_wire (mint, &wire_cb, is); trigger_context_task (); return; default: GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unknown instruction %d at %u (%s)\n", cmd->oc, is->ip, cmd->label); fail (is); return; } is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Function run when the test terminates (good or bad). * Cleans up our state. * * @param cls the interpreter state. * @param tc unused */ static void do_shutdown (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct InterpreterState *is = cls; struct Command *cmd; unsigned int i; shutdown_task = NULL; for (i=0;OC_END != (cmd = &is->commands[i])->oc;i++) { switch (cmd->oc) { case OC_END: GNUNET_assert (0); break; case OC_ADMIN_ADD_INCOMING: if (NULL != cmd->details.admin_add_incoming.aih) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_admin_add_incoming_cancel (cmd->details.admin_add_incoming.aih); cmd->details.admin_add_incoming.aih = NULL; } break; case OC_WITHDRAW_STATUS: if (NULL != cmd->details.reserve_status.wsh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_reserve_status_cancel (cmd->details.reserve_status.wsh); cmd->details.reserve_status.wsh = NULL; } break; case OC_WITHDRAW_SIGN: if (NULL != cmd->details.reserve_withdraw.wsh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_reserve_withdraw_cancel (cmd->details.reserve_withdraw.wsh); cmd->details.reserve_withdraw.wsh = NULL; } if (NULL != cmd->details.reserve_withdraw.sig.rsa_signature) { GNUNET_CRYPTO_rsa_signature_free (cmd->details.reserve_withdraw.sig.rsa_signature); cmd->details.reserve_withdraw.sig.rsa_signature = NULL; } if (NULL != cmd->details.reserve_withdraw.blinding_key.rsa_blinding_key) { GNUNET_CRYPTO_rsa_blinding_key_free (cmd->details.reserve_withdraw.blinding_key.rsa_blinding_key); cmd->details.reserve_withdraw.blinding_key.rsa_blinding_key = NULL; } break; case OC_DEPOSIT: if (NULL != cmd->details.deposit.dh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_deposit_cancel (cmd->details.deposit.dh); cmd->details.deposit.dh = NULL; } break; case OC_REFRESH_MELT: if (NULL != cmd->details.refresh_melt.rmh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_refresh_melt_cancel (cmd->details.refresh_melt.rmh); cmd->details.refresh_melt.rmh = NULL; } GNUNET_free_non_null (cmd->details.refresh_melt.fresh_pks); cmd->details.refresh_melt.fresh_pks = NULL; GNUNET_free_non_null (cmd->details.refresh_melt.refresh_data); cmd->details.refresh_melt.refresh_data = NULL; cmd->details.refresh_melt.refresh_data_length = 0; break; case OC_REFRESH_REVEAL: if (NULL != cmd->details.refresh_reveal.rrh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_refresh_reveal_cancel (cmd->details.refresh_reveal.rrh); cmd->details.refresh_reveal.rrh = NULL; } { unsigned int j; struct FreshCoin *fresh_coins; fresh_coins = cmd->details.refresh_reveal.fresh_coins; for (j=0;jdetails.refresh_reveal.num_fresh_coins;j++) GNUNET_CRYPTO_rsa_signature_free (fresh_coins[j].sig.rsa_signature); } GNUNET_free_non_null (cmd->details.refresh_reveal.fresh_coins); cmd->details.refresh_reveal.fresh_coins = NULL; cmd->details.refresh_reveal.num_fresh_coins = 0; break; case OC_REFRESH_LINK: if (NULL != cmd->details.refresh_link.rlh) { GNUNET_log (GNUNET_ERROR_TYPE_WARNING, "Command %u (%s) did not complete\n", i, cmd->label); TALER_MINT_refresh_link_cancel (cmd->details.refresh_link.rlh); cmd->details.refresh_link.rlh = NULL; } break; case OC_WIRE: if (NULL != cmd->details.wire.wh) { TALER_MINT_wire_cancel (cmd->details.wire.wh); cmd->details.wire.wh = NULL; } break; default: GNUNET_log (GNUNET_ERROR_TYPE_ERROR, "Unknown instruction %d at %u (%s)\n", cmd->oc, i, cmd->label); break; } } if (NULL != is->task) { GNUNET_SCHEDULER_cancel (is->task); is->task = NULL; } GNUNET_free (is); if (NULL != ctx_task) { GNUNET_SCHEDULER_cancel (ctx_task); ctx_task = NULL; } if (NULL != mint) { TALER_MINT_disconnect (mint); mint = NULL; } if (NULL != ctx) { TALER_MINT_fini (ctx); ctx = NULL; } } /** * Functions of this type are called to provide the retrieved signing and * denomination keys of the mint. No TALER_MINT_*() functions should be called * in this callback. * * @param cls closure * @param keys information about keys of the mint */ static void cert_cb (void *cls, const struct TALER_MINT_Keys *keys) { struct InterpreterState *is = cls; /* check that keys is OK */ #define ERR(cond) do { if(!(cond)) break; GNUNET_break (0); GNUNET_SCHEDULER_shutdown(); return; } while (0) ERR (NULL == keys); ERR (0 == keys->num_sign_keys); GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Read %u signing keys\n", keys->num_sign_keys); ERR (0 == keys->num_denom_keys); GNUNET_log (GNUNET_ERROR_TYPE_DEBUG, "Read %u denomination keys\n", keys->num_denom_keys); #undef ERR /* run actual tests via interpreter-loop */ is->keys = keys; is->task = GNUNET_SCHEDULER_add_now (&interpreter_run, is); } /** * Task that runs the context's event loop with the GNUnet scheduler. * * @param cls unused * @param tc scheduler context (unused) */ static void context_task (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { long timeout; int max_fd; fd_set read_fd_set; fd_set write_fd_set; fd_set except_fd_set; struct GNUNET_NETWORK_FDSet *rs; struct GNUNET_NETWORK_FDSet *ws; struct GNUNET_TIME_Relative delay; ctx_task = NULL; TALER_MINT_perform (ctx); max_fd = -1; timeout = -1; FD_ZERO (&read_fd_set); FD_ZERO (&write_fd_set); FD_ZERO (&except_fd_set); TALER_MINT_get_select_info (ctx, &read_fd_set, &write_fd_set, &except_fd_set, &max_fd, &timeout); if (timeout >= 0) delay = GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_MILLISECONDS, timeout); else delay = GNUNET_TIME_UNIT_FOREVER_REL; rs = GNUNET_NETWORK_fdset_create (); GNUNET_NETWORK_fdset_copy_native (rs, &read_fd_set, max_fd + 1); ws = GNUNET_NETWORK_fdset_create (); GNUNET_NETWORK_fdset_copy_native (ws, &write_fd_set, max_fd + 1); ctx_task = GNUNET_SCHEDULER_add_select (GNUNET_SCHEDULER_PRIORITY_DEFAULT, delay, rs, ws, &context_task, cls); GNUNET_NETWORK_fdset_destroy (rs); GNUNET_NETWORK_fdset_destroy (ws); } /** * Main function that will be run by the scheduler. * * @param cls closure * @param args remaining command-line arguments * @param cfgfile name of the configuration file used (for saving, can be NULL!) * @param config configuration */ static void run (void *cls, const struct GNUNET_SCHEDULER_TaskContext *tc) { struct InterpreterState *is; static struct MeltDetails melt_coins_1[] = { { .amount = "EUR:4", .coin_ref = "refresh-withdraw-coin-1" }, { NULL, NULL } }; static const char *melt_fresh_amounts_1[] = { "EUR:1", "EUR:1", "EUR:1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.1", "EUR:0.01", "EUR:0.01", "EUR:0.01", "EUR:0.01", "EUR:0.01", "EUR:0.01", /* with 0.01 withdraw fees (except for 1ct coins), this totals up to exactly EUR:3.97, and with the 0.03 refresh fee, to EUR:4.0*/ NULL }; static struct Command commands[] = { /* *************** start of /wire testing ************** */ #if WIRE_TEST { .oc = OC_WIRE, .label = "wire-test", /* /wire/test replies with a 302 redirect */ .expected_response_code = MHD_HTTP_FOUND, .details.wire.format = "test" }, #endif #if WIRE_SEPA { .oc = OC_WIRE, .label = "wire-sepa", /* /wire/sepa replies with a 200 redirect */ .expected_response_code = MHD_HTTP_OK, .details.wire.format = "sepa" }, #endif /* *************** end of /wire testing ************** */ #if WIRE_TEST /* None of this works if 'test' is not allowed as we do /admin/add/incoming with format 'test' */ /* Fill reserve with EUR:5.01, as withdraw fee is 1 ct per config */ { .oc = OC_ADMIN_ADD_INCOMING, .label = "create-reserve-1", .expected_response_code = MHD_HTTP_OK, .details.admin_add_incoming.wire = "{ \"type\":\"TEST\", \"bank\":\"source bank\", \"account\":42 }", .details.admin_add_incoming.amount = "EUR:5.01" }, /* Withdraw a 5 EUR coin, at fee of 1 ct */ { .oc = OC_WITHDRAW_SIGN, .label = "withdraw-coin-1", .expected_response_code = MHD_HTTP_OK, .details.reserve_withdraw.reserve_reference = "create-reserve-1", .details.reserve_withdraw.amount = "EUR:5" }, /* Check that deposit and withdraw operation are in history, and that the balance is now at zero */ { .oc = OC_WITHDRAW_STATUS, .label = "withdraw-status-1", .expected_response_code = MHD_HTTP_OK, .details.reserve_status.reserve_reference = "create-reserve-1", .details.reserve_status.expected_balance = "EUR:0" }, /* Try to deposit the 5 EUR coin (in full) */ { .oc = OC_DEPOSIT, .label = "deposit-simple", .expected_response_code = MHD_HTTP_OK, .details.deposit.amount = "EUR:5", .details.deposit.coin_ref = "withdraw-coin-1", .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":1 } }", .details.deposit.transaction_id = 1 }, /* Try to overdraw funds ... */ { .oc = OC_WITHDRAW_SIGN, .label = "withdraw-coin-2", .expected_response_code = MHD_HTTP_PAYMENT_REQUIRED, .details.reserve_withdraw.reserve_reference = "create-reserve-1", .details.reserve_withdraw.amount = "EUR:5" }, /* Try to double-spend the 5 EUR coin with different wire details */ { .oc = OC_DEPOSIT, .label = "deposit-double-1", .expected_response_code = MHD_HTTP_FORBIDDEN, .details.deposit.amount = "EUR:5", .details.deposit.coin_ref = "withdraw-coin-1", .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":43 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":1 } }", .details.deposit.transaction_id = 1 }, /* Try to double-spend the 5 EUR coin at the same merchant (but different transaction ID) */ { .oc = OC_DEPOSIT, .label = "deposit-double-2", .expected_response_code = MHD_HTTP_FORBIDDEN, .details.deposit.amount = "EUR:5", .details.deposit.coin_ref = "withdraw-coin-1", .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":1 } }", .details.deposit.transaction_id = 2 }, /* Try to double-spend the 5 EUR coin at the same merchant (but different contract) */ { .oc = OC_DEPOSIT, .label = "deposit-double-3", .expected_response_code = MHD_HTTP_FORBIDDEN, .details.deposit.amount = "EUR:5", .details.deposit.coin_ref = "withdraw-coin-1", .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":2 } }", .details.deposit.transaction_id = 1 }, /* ***************** /refresh testing ******************** */ /* Fill reserve with EUR:5.01, as withdraw fee is 1 ct */ { .oc = OC_ADMIN_ADD_INCOMING, .label = "refresh-create-reserve-1", .expected_response_code = MHD_HTTP_OK, .details.admin_add_incoming.wire = "{ \"type\":\"TEST\", \"bank\":\"source bank\", \"account\":424 }", .details.admin_add_incoming.amount = "EUR:5.01" }, /* Withdraw a 5 EUR coin, at fee of 1 ct */ { .oc = OC_WITHDRAW_SIGN, .label = "refresh-withdraw-coin-1", .expected_response_code = MHD_HTTP_OK, .details.reserve_withdraw.reserve_reference = "refresh-create-reserve-1", .details.reserve_withdraw.amount = "EUR:5" }, /* Try to partially spend (deposit) 1 EUR of the 5 EUR coin (in full) (merchant would receive EUR:0.99 due to 1 ct deposit fee) */ { .oc = OC_DEPOSIT, .label = "refresh-deposit-partial", .expected_response_code = MHD_HTTP_OK, .details.deposit.amount = "EUR:1", .details.deposit.coin_ref = "refresh-withdraw-coin-1", .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\"EUR:1 } }", .details.deposit.transaction_id = 42421 }, /* Melt the rest of the coin's value (EUR:4.00 = 3x EUR:1.03 + 7x EUR:0.13) */ { .oc = OC_REFRESH_MELT, .label = "refresh-melt-1", .expected_response_code = MHD_HTTP_OK, .details.refresh_melt.melted_coins = melt_coins_1, .details.refresh_melt.fresh_amounts = melt_fresh_amounts_1 }, /* Complete (successful) melt operation, and withdraw the coins */ { .oc = OC_REFRESH_REVEAL, .label = "refresh-reveal-1", .expected_response_code = MHD_HTTP_OK, .details.refresh_reveal.melt_ref = "refresh-melt-1" }, /* Test that /refresh/link works */ { .oc = OC_REFRESH_LINK, .label = "refresh-link-1", .expected_response_code = MHD_HTTP_OK, .details.refresh_link.reveal_ref = "refresh-reveal-1" }, /* Test successfully spending coins from the refresh operation: first EUR:1 */ { .oc = OC_DEPOSIT, .label = "refresh-deposit-refreshed-1a", .expected_response_code = MHD_HTTP_OK, .details.deposit.amount = "EUR:1", .details.deposit.coin_ref = "refresh-reveal-1", .details.deposit.coin_idx = 0, .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":3 } }", .details.deposit.transaction_id = 2 }, /* Test successfully spending coins from the refresh operation: finally EUR:0.1 */ { .oc = OC_DEPOSIT, .label = "refresh-deposit-refreshed-1b", .expected_response_code = MHD_HTTP_OK, .details.deposit.amount = "EUR:0.1", .details.deposit.coin_ref = "refresh-reveal-1", .details.deposit.coin_idx = 4, .details.deposit.wire_details = "{ \"type\":\"TEST\", \"bank\":\"dest bank\", \"account\":42 }", .details.deposit.contract = "{ \"items\"={ \"name\":\"ice cream\", \"value\":3 } }", .details.deposit.transaction_id = 2 }, /* Test running a failing melt operation (same operation again must fail) */ { .oc = OC_REFRESH_MELT, .label = "refresh-melt-failing", .expected_response_code = MHD_HTTP_FORBIDDEN, .details.refresh_melt.melted_coins = melt_coins_1, .details.refresh_melt.fresh_amounts = melt_fresh_amounts_1 }, // FIXME: also test with coin that was already melted // (signature differs from coin that was deposited...) /* *************** end of /refresh testing ************** */ #endif { .oc = OC_END } }; is = GNUNET_new (struct InterpreterState); is->commands = commands; ctx = TALER_MINT_init (); GNUNET_assert (NULL != ctx); ctx_task = GNUNET_SCHEDULER_add_now (&context_task, ctx); mint = TALER_MINT_connect (ctx, "http://localhost:8081", &cert_cb, is, TALER_MINT_OPTION_END); GNUNET_assert (NULL != mint); shutdown_task = GNUNET_SCHEDULER_add_delayed (GNUNET_TIME_relative_multiply (GNUNET_TIME_UNIT_SECONDS, 150), &do_shutdown, is); } /** * Main function for the testcase for the mint API. * * @param argc expected to be 1 * @param argv expected to only contain the program name */ int main (int argc, char * const *argv) { struct GNUNET_OS_Process *proc; struct GNUNET_OS_Process *mintd; GNUNET_log_setup ("test-mint-api", "WARNING", NULL); proc = GNUNET_OS_start_process (GNUNET_NO, GNUNET_OS_INHERIT_STD_ALL, NULL, NULL, NULL, "taler-mint-keyup", "taler-mint-keyup", "-d", "test-mint-home", "-m", "test-mint-home/master.priv", NULL); GNUNET_OS_process_wait (proc); GNUNET_OS_process_destroy (proc); mintd = GNUNET_OS_start_process (GNUNET_NO, GNUNET_OS_INHERIT_STD_ALL, NULL, NULL, NULL, "taler-mint-httpd", "taler-mint-httpd", "-d", "test-mint-home", NULL); /* give child time to start and bind against the socket */ fprintf (stderr, "Waiting for taler-mint-httpd to be ready"); do { fprintf (stderr, "."); sleep (1); } while (0 != system ("wget -q -t 1 -T 1 http://127.0.0.1:8081/keys -o /dev/null -O /dev/null")); fprintf (stderr, "\n"); result = GNUNET_SYSERR; GNUNET_SCHEDULER_run (&run, NULL); GNUNET_OS_process_kill (mintd, SIGTERM); GNUNET_OS_process_wait (mintd); GNUNET_OS_process_destroy (mintd); return (GNUNET_OK == result) ? 0 : 1; } /* end of test_mint_api.c */