976 lines
31 KiB
Plaintext
976 lines
31 KiB
Plaintext
\input texinfo @c -*-texinfo-*-
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@setfilename taler-exchange.info
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@documentencoding UTF-8
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@include version.texi
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@settitle The GNU Taler Exchange Operator Manual
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@paragraphindent 0
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@exampleindent 4
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@include syntax.texi
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@copying
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This manual is for the GNU Taler Exchange
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(version @value{VERSION}, @value{UPDATED}),
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a payment service provider for GNU Taler.
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Copyright @copyright{} 2014-2017 GNUnet e.V. and INRIA
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@quotation
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Permission is granted to copy, distribute and/or modify this document
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under the terms of the GNU Free Documentation License, Version 1.3
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or any later version published by the Free Software Foundation;
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with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
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Texts. A copy of the license is included in the section entitled "GNU
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Free Documentation License".
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@end quotation
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@end copying
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@dircategory Network applications
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@direntry
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* GNU Taler Exchange: (taler-exchange). Electronic payment system.
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@end direntry
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@titlepage
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@title The GNU Taler Exchange Operator Manual
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@subtitle Version @value{VERSION}
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@subtitle @value{UPDATED}
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@author Christian Grothoff (@email{grothoff@@taler.net})
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@author Marcello Stanisci (@email{stanisci@@taler.net})
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@page
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@vskip 0pt plus 1filll
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@insertcopying
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@end titlepage
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@summarycontents
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@contents
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@ifnottex
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@node Top
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@top The GNU Taler Exchange Operator Manual
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@insertcopying
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@end ifnottex
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@menu
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* Introduction::
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* Installation::
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* Configuration::
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* Deployment::
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* Diagnostics::
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Appendices
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* GNU-AGPL:: The GNU Affero General Public License says how you
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can copy and share the code of the `GNU Taler Exchange'.
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* GNU-FDL:: The GNU Free Documentation License says how you
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can copy and share the documentation of `GNU Taler'.
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Indices
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* Concept Index:: Index of concepts and programs.
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@end menu
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@node Introduction
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@chapter Introduction
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This manual is an early draft that still needs significant editing
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work to become readable.
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@section About GNU Taler
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GNU Taler is an open protocol for an electronic payment system with a
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free software reference implementation. GNU Taler offers secure, fast
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and easy payment processing using well understood cryptographic
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techniques. GNU Taler allows customers to remain anonymous, while
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ensuring that merchants can be held accountable by governments.
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Hence, GNU Taler is compatible with anti-money-laundering (AML) and
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know-your-customer (KYC) regulation, as well as data protection
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regulation (such as GDPR).
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GNU Taler is not yet production-ready, after following this manual
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you will have a backend that can process payments in ``KUDOS'', but
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not regular currencies. This is not so much because of limitations
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in the backend, but because we are not aware of a Taler exchange
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operator offering regular currencies today.
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@section About this manual
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This tutorial targets system administrators who want to install and
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operate a GNU Taler exchange.
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@section Organizational prerequisites
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Operating a GNU Taler exchange means that you are operating a payment
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service provider, which means that you will most likely need a bank
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license and/or follow applicable financial regulation.
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@cindex availability
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@cindex backup
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@cindex replication
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GNU Taler payment service providers generally need to ensure high
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availability and have @emph{really} good backups (synchronous
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replication, asynchronous remote replication, off-site backup, 24/7
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monitoring, etc.).@footnote{Naturally, you could operate a Taler
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exchange for a toy currency without any real value on low-cost setups
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like a Raspberry Pi, but we urge you to limit the use of such setups
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to research and education as with GNU Taler data loss instantly
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results in financial losses.} This manual will not cover these
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aspects of operating a payment service provider.
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@cindex HSM
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@cindex offline
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@cindex database
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@cindex operational security
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We will assume that you can operate a (high-availability,
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high-assurance) Postgres database. Furthermore, we expect some
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moderate familiarity with the compilation and installation of free
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software packages. You need to understand the cryptographic concepts
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of private and public keys and must be able to protect private keys
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stored in files on disk. An exchange uses an @emph{offline} master
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key as well as @emph{online} keys. You are advised to secure your
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private master key and any copies on encrypted, always-offline
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computers. Again, we assume that you are familiar with good best
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practices in operational security, including securing key
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material.@footnote{The current implementation does not make provisions
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for secret splitting. Still, the use of a hardware security module
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(HSM) for protecting private keys is adviseable, so please contact the
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developers for HSM integration support.}
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@section Architecture overview
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@cindex crypto-currency
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@cindex bank
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@cindex escrow
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@cindex coin
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Taler is a pure payment system, not a new crypto-currency. As such, it
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operates in a traditional banking context. In particular, this means
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that in order to receive funds via Taler, the merchant must have a
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regular bank account, and payments can be executed in ordinary
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currencies such as USD or EUR. Similarly, the Taler exchange must
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interact with a bank. The bank of the exchange holds the exchange's
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funds in an escrow account.
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@cindex reserve
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@cindex fee
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@cindex aggregator
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@cindex deposit
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When customers wire money to the escrow account, the bank notifies
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the exchange about the incoming wire transfers. The exchange then
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creates a @emph{reserve} based on the subject of the wire transfer.
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The wallet which knows the secret key matching the wire transfer
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subject can then withdraw coins from the reserve, thereby draining
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it. The liability of the exchange against the reserve is thereby
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converted into a liability against digital coins issued by the
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exchange. When the customer later spends the coins at a merchant,
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and the merchant @emph{deposits} the coins at the exchange, the
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exchange first @emph{aggregates} the amount from multiple deposits
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from the same merchant and then instructs its bank to make a
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wire transfer to the merchant, thereby fulfilling its obligation
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and eliminating the liability. The exchange charges @emph{fees}
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for some or all of its operations to cover costs and possibly make
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a profit.
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@cindex auditor
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@cindex accounting
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@emph{Auditors} are third parties, for example financial regulators,
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that verify that the exchange operates correctly. The same software
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is also used to calculate the exchange's profits, risk and liabilities
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by the accountants of the exchange.
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The Taler software stack for an exchange consists of the
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following components:
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@itemize
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@cindex HTTP frontend
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@item The HTTP frontend interacts with Taler wallets and
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merchant backends. It is used to withdraw coins, deposit
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coins, refresh coins, issue refunds, map wire transfers to
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Taler transactions, inquire about the exchange's bank account
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details, signing keys and fee structure.
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The binary is the @code{taler-exchange-httpd}.
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@cindex Aggregator
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@item The aggregator combines multiple deposits made by
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the same merchant and (eventually) triggers wire transfers for the
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aggregate amount. The merchant can control how quickly wire
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transfers are made. The exchange may be charge a fee per wire transfer
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to discourage excessively frequent transfers. The binary
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is the @code{taler-exchange-aggregator}.
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@cindex Auditor
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@item The auditor verifies that the transactions performed by
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the exchange were done properly. It checks the various signatures,
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totals up the amounts and alerts the operator to any inconsistencies.
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It also computes the expected bank balance, revenue and risk exposure
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of the exchange operator. The main binary is the
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@code{taler-auditor}.
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@cindex Wire plugin
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@item A wire plugin enables the HTTP frontend to talk to the
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bank. Its role is to allow the exchange to validate bank
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addresses (i.e. IBAN numbers), for the aggregator to execute
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wire transfers and for the auditor to query bank transaction
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histories. Wire plugins are @emph{plugins} as there can be
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many different implementations to deal with different
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banking standards. Wire plugins are automatically located
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and used by the exchange, aggregator and auditor.
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@cindex DBMS
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@cindex Postgres
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@item The exchange requires a DBMS to stores the transaction history for
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the Taler exchange and aggregator, and a (typically separate) DBMS for
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the Taler auditor.
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For now, the GNU Taler reference implemenation only supports Postgres,
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but the code could be easily extended to support another DBMS.
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@end itemize
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@c The following image illustrates the various interactions of these
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@c key components:
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@c @center @image{arch, 3in, 4in}
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@node Installation
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@chapter Installation
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Please install the following packages before proceeding with the exchange compilation.
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@itemize
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@item
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GNU autoconf @geq{} 2.69
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@item
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GNU automake @geq{} 1.14
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@item
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GNU libtool @geq{} 2.4
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@item
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GNU autopoint @geq{} 0.19
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@item
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GNU libltdl @geq{} 2.4
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@item
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GNU libunistring @geq{} 0.9.3
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@item
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libcurl @geq{} 7.26 (or libgnurl @geq{} 7.26)
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@item
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GNU libmicrohttpd @geq{} 0.9.52
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@item
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GNU libgcrypt @geq{} 1.6
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@item
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libjansson @geq{} 2.7
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@item
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Postgres @geq{} 9.6, including libpq
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@item
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libgnunetutil (from Git)
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@item
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GNU Taler exchange (from Git)
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@end itemize
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Except for the last two, these are available in most GNU/Linux
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distributions and should just be installed using the respective
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package manager.
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The following instructions will show how to install libgnunetutil and
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the GNU Taler exchange.
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Before you install libgnunetutil, you must download and install the
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dependencies mentioned above, otherwise the build may succeed but fail
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to export some of the tooling required by Taler.
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To download and install libgnunetutil, proceed as follows:
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@example
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$ git clone https://gnunet.org/git/gnunet/
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$ cd gnunet/
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$ ./bootstrap
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$ ./configure [--prefix=GNUNETPFX]
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$ # Each dependency can be fetched from non standard locations via
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$ # the '--with-<LIBNAME>' option. See './configure --help'.
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$ make
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# make install
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@end example
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If you did not specify a prefix, GNUnet will install to
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@code{/usr/local}, which requires you to run the last step as
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@code{root}.
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To download and install the GNU Taler exchange, proceeds as follows:
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@setsyntax shell
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@example
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$ git clone git://taler.net/exchange
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$ cd exchange
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$ ./bootstrap
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$ ./configure [--prefix=EXCHANGEPFX] \
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[--with-gnunet=GNUNETPFX]
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$ # Each dependency can be fetched from non standard locations via
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$ # the '--with-<LIBNAME>' option. See './configure --help'.
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$ make
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# make install
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@end example
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If you did not specify a prefix, the exchange will install to
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@code{/usr/local}, which requires you to run the last step as
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@code{root}. Note that you have to specify @code{--with-gnunet=/usr/local}
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if you installed GNUnet to @code{/usr/local} in the previous step.
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@node Configuration
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@chapter Configuration
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@c In this document, we assume that @code{$HOME/.config/taler.conf} is being customized.
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This chapter provides an overview of the exchange configuration. Or
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at least eventually will do so, for now it is a somewhat wild
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description of some of the options.
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@menu
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* Keying::
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* Serving::
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* Currency::
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* Bank account::
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* Database::
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* Coins (denomination keys): Coins denomination keys.
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* Keys duration::
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@end menu
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@node Keying
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@section Keying
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The exchange works with three types of keys:
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@itemize
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@item
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@cite{master key}
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@item
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@cite{sign keys}
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@item
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@cite{denomination keys} (see section @cite{Coins})
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@end itemize
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@cite{master key}: in section @cite{[exchange]}, edit the two following values:
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@itemize
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@item
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@cite{master_priv_file}: Path to the exchange's master private file.
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@item
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@cite{master_public_key}: Must specify the exchange's master public key.
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@end itemize
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@cite{sign keys}: the following two options under
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@cite{[exchange_keys]} section control @cite{sign keys}:
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@itemize
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@item
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@cite{signkey_duration}: How long should one signing key be used?
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@item
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@cite{lookahead_sign}: How much time we want to cover with our
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@cite{signkeys}? Note that if @cite{signkey_duration} is bigger than
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@cite{lookahead_sign}, @cite{taler-exchange-keyup} will generate a
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quantity of @cite{signkeys} which is sufficient to cover all the
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gap. See keys-duration.
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@end itemize
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@node Serving
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@section Serving
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The exchange can serve HTTP over both TCP and UNIX domain socket.
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The following values are to be configured in the section
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@cite{[exchange]}:
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@itemize
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@item
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@cite{serve}: must be set to @cite{tcp} to serve HTTP over TCP, or
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@cite{unix} to serve HTTP over a UNIX domain socket
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@item
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@cite{port}: Set to the TCP port to listen on if @cite{serve} Is
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@cite{tcp}.
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@item
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@cite{unixpath}: set to the UNIX domain socket path to listen on if
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@cite{serve} Is @cite{unix}
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@item
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@cite{unixpath_mode}: number giving the mode with the access
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permission MASK for the @cite{unixpath} (i.e. 660 = rw-rw----).
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@end itemize
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@node Currency
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@section Currency
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The exchange supports only one currency. This data is set under the respective
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option @cite{currency} in section @cite{[taler]}.
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@node Bank account
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@section Bank account
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@menu
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* Wiremethod-test::
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* Wiremethod-sepa::
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@end menu
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@node Wiremethod-test
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@subsection Wiremethod-test
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To enable the wire transfer method ``test'', you need to set
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``ENABLE=YES'' in section @cite{[exchange-wire-test]}.
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The bank account where the exchange gets money from customers is
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configured under the section @cite{[exchange-wire-test]}. It must
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contain the options ``EXCHANGE_ACCOUNT_NO'' and ``BANK_URI''.
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For basic authentication, it must additionally contain the
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``USERNAME'' and ``PASSWORD'' of the exchange's account at the bank.
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For incoming transfers, the section must additional contain the
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option: @cite{test_response_file}, which takes
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the path to a text file containing the exchange's bank account details
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in JSON format.
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The command line tool @cite{taler-exchange-wire} is used to create such a file.
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For example, the utility may be invoked as follows:
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@example
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$ taler-exchange-wire -j '@{"name": "The Exchange", "account_number":
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10, "bank_uri": "https://bank.demo.taler.net", "type": "test"@}' -t
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test -o exchange.json
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@end example
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Note that the value given to option @cite{-t} must match the value in
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the JSON's field @code{"type"}.
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The generated file will be echoed by the exchange when serving
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/wire@footnote{https://api.taler.net/api-exchange.html#wire-req}
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requests.
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@node Wiremethod-sepa
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@subsection Wiremethod-sepa
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To enable the wire transfer method ``sepa'', you need to set
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``ENABLE=YES'' in section @cite{[exchange-wire-sepa]}.
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This section contains only one option: @cite{sepa_response_file},
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which takes the path to a text file containing the exchange's bank
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account details in JSON format.
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The command line tool @cite{taler-exchange-wire} is used to create such a file.
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For example, the utility may be invoked as follows:
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@example
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$ taler-exchange-wire -j '@{"name": "The Exchange", "account_number":
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10, "bank_uri": "https://bank.demo.taler.net", "type": "sepa"@}' -t
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sepa -o exchange.json
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@end example
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Note that the value given to option @cite{-t} must match the value in the JSON's field @code{"type"}.
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The generated file will be echoed by the exchange when serving
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/wire@footnote{https://api.taler.net/api-exchange.html#wire-req}
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requests.
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This exchange's outgoing bank account is used to give money to merchants, after
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successful
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deposits@footnote{https://api.taler.net/api-exchange.html#deposit-par}
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operations. The outgoing bank account is configured by the following
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options under @cite{[exchange-wire-outgoing-sepa]}: (NOT YET SUPPORTED).
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@quotation
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@itemize
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@item
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@cite{exchange_account_numer}: which bank account number has the exchange
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@item
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@cite{bank_uri}: base URL of the bank hosting the exchange bank account
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@end itemize
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@end quotation
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@cartouche
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@quotation Note
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The rationale behind having two bank accounts is that the exchange operator, as a security
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measure, may want to instruct the bank that the incoming bank account is only supposed to
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@emph{receive} money.
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@end quotation
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@end cartouche
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@node Database
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@section Database
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The option @cite{db} under section @cite{[exchange]} gets the DB backend's name the exchange
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is going to use. So far, only @cite{db = postgres} is supported. After choosing the backend,
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it is mandatory to supply the connection string (namely, the database name). This is
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possible in two ways:
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@itemize
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@item
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via an environment variable: @cite{TALER_EXCHANGEDB_POSTGRES_CONFIG}.
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@item
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via configuration option @cite{db_conn_str}, under section @cite{[exchangedb-BACKEND]}. For example, the demo exchange is configured as follows:
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@end itemize
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@setsyntax ini
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@example
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[exchange]
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...
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db = postgres
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...
|
|
|
|
[exchangedb-postgres]
|
|
db_conn_str = postgres:///talerdemo
|
|
@end example
|
|
|
|
@node Coins denomination keys
|
|
@section Coins (denomination keys)
|
|
|
|
|
|
Sections specifying denomination (coin) information start with
|
|
"coin_". By convention, the name continues with
|
|
"$CURRENCY_[$SUBUNIT]_$VALUE", i.e. @cite{[coin_eur_ct_10]} for a 10
|
|
cent piece. However, only the "coin_" prefix is mandatory. Each
|
|
"coin_"-section must then have the following options:
|
|
|
|
|
|
@itemize
|
|
|
|
@item
|
|
@cite{value}: How much is the coin worth, the format is
|
|
CURRENCY:VALUE.FRACTION. For example, a 10 cent piece is "EUR:0.10".
|
|
|
|
@item
|
|
@cite{duration_withdraw}: How long can a coin of this type be
|
|
withdrawn? This limits the losses incurred by the exchange when a
|
|
denomination key is compromised.
|
|
|
|
@item
|
|
@cite{duration_overlap}: What is the overlap of the withdrawal
|
|
timespan for this coin type?
|
|
|
|
@item
|
|
@cite{duration_spend}: How long is a coin of the given type valid?
|
|
Smaller values result in lower storage costs for the exchange.
|
|
|
|
@item
|
|
@cite{fee_withdraw}: What does it cost to withdraw this coin?
|
|
Specified using the same format as @cite{value}.
|
|
|
|
@item
|
|
@cite{fee_deposit}: What does it cost to deposit this coin? Specified
|
|
using the same format as @cite{value}.
|
|
|
|
@item
|
|
@cite{fee_refresh}: What does it cost to refresh this coin? Specified
|
|
using the same format as @cite{value}.
|
|
|
|
@item
|
|
@cite{rsa_keysize}: How many bits should the RSA modulus (product of
|
|
the two primes) have for this type of coin.
|
|
@end itemize
|
|
|
|
|
|
@node Keys duration
|
|
@section Keys duration
|
|
|
|
|
|
Both @cite{signkeys} and @cite{denom keys} have a starting date. The
|
|
option @cite{lookahead_provide}, under section @cite{[exchange_keys]},
|
|
is such that only keys whose starting date is younger than
|
|
@cite{lookahead_provide} will be issued by the exchange.
|
|
|
|
@cite{signkeys}. The option @cite{lookahead_sign} is such that, being
|
|
@cite{t} the time when @cite{taler-exchange-keyup} is run,
|
|
@cite{taler-exchange-keyup} will generate @cite{n} @cite{signkeys},
|
|
where @cite{t + (n * signkey_duration) = t + lookahead_sign}. In other
|
|
words, we generate a number of keys which is sufficient to cover a
|
|
period of @cite{lookahead_sign}. As for the starting date, the first
|
|
generated key will get a starting time of @cite{t}, and the
|
|
@cite{j}-th key will get a starting time of @cite{x +
|
|
signkey_duration}, where @cite{x} is the starting time of the
|
|
@cite{(j-1)}-th key.
|
|
|
|
@cite{denom keys}. The option @cite{lookahead_sign} is such that,
|
|
being @cite{t} the time when @cite{taler-exchange-keyup} is run,
|
|
@cite{taler-exchange-keyup} will generate @cite{n} @cite{denom keys}
|
|
for each denomination, where @cite{t + (n * duration_withdraw) = t +
|
|
lookahead_sign}. In other words, for each denomination, we generate a
|
|
number of keys which is sufficient to cover a period of
|
|
@cite{lookahead_sign}. As for the starting date, the first generated
|
|
key will get a starting time of @cite{t}, and the @cite{j}-th key will
|
|
get a starting time of @cite{x + duration_withdraw}, where @cite{x} is
|
|
the starting time of the @cite{(j-1)}-th key.
|
|
|
|
@node Deployment
|
|
@chapter Deployment
|
|
|
|
|
|
@menu
|
|
* Keys generation::
|
|
* Database upgrades::
|
|
@end menu
|
|
|
|
@node Keys generation
|
|
@section Keys generation
|
|
|
|
Once the configuration is properly set up, all the keys can be generated
|
|
by the tool @code{taler-exchange-keyup}. The following command generates denomkeys
|
|
and signkeys, plus the "blob" that is to be signed by the auditor.
|
|
|
|
@example
|
|
taler-exchange-keyup -o blob
|
|
@end example
|
|
|
|
@emph{blob} contains data about denomkeys that the exchange operator needs to
|
|
get signed by every auditor he wishes (or is forced to) work with.
|
|
|
|
In a normal scenario, an auditor must have some way of receiving the blob to
|
|
sign (Website, manual delivery, ..). Nonetheless, the exchange admin can fake
|
|
an auditor signature --- for testing purposes --- by running the following command
|
|
|
|
@example
|
|
taler-auditor-sign -m EXCHANGE_MASTER_PUB -r BLOB -u AUDITOR_URI -o OUTPUT_FILE
|
|
@end example
|
|
|
|
Those arguments are all mandatory.
|
|
|
|
@itemize
|
|
@item @code{EXCHANGE_MASTER_PUB} the base32 Crockford-encoded exchange's master
|
|
public key. Tipically, this value lies in the configuration option
|
|
@code{[exchange]/master_public_key}.
|
|
@item @code{BLOB} the blob generated in the previous step.
|
|
@item @code{AUDITOR_URI} the URI that identifies the auditor.
|
|
@item @code{OUTPUT_FILE} where on the disk the signed blob is to be saved.
|
|
@end itemize
|
|
|
|
@code{OUTPUT_FILE} must then be copied into the directory specified
|
|
by the option @code{AUDITOR_BASE_DIR} under the section @code{[exchangedb]}.
|
|
Assuming @code{AUDITOR_BASE_DIR = $@{HOME@}/.local/share/taler/auditors}, the
|
|
following command will "add" the auditor identified by @code{AUDITOR_URI} to
|
|
the exchange.
|
|
|
|
@example
|
|
cp OUTPUT_FILE $@{HOME@}/.local/share/taler/auditors
|
|
@end example
|
|
|
|
If the auditor has been correctly added, the exchange's @code{/keys} response
|
|
must contain an entry in the @code{auditors} array mentioning the auditor's URI.
|
|
|
|
|
|
@c FIXME: reference section about where keys are stored.
|
|
|
|
@node Database upgrades
|
|
@section Database upgrades
|
|
|
|
Currently, there is no way to upgrade the database between Taler versions.
|
|
|
|
The exchange database can be re-initialized using:
|
|
|
|
@example
|
|
$ taler-exchange-dbinit -r
|
|
@end example
|
|
|
|
However, running this command will result in all data in the database
|
|
being lost, which may result in significant financial liabilities as
|
|
the exchange can then not detect double-spending. Hence this
|
|
operation must not be performed in a production system.
|
|
|
|
@node Diagnostics
|
|
@chapter Diagnostics
|
|
|
|
This chapter includes various (very unpolished) sections on specific topics
|
|
that might be helpful to understand how the exchange operates, which files
|
|
should be backed up. The information may also be helpful for diagnostics.
|
|
|
|
@menu
|
|
* Configuration format::
|
|
* Reserve management::
|
|
* Database Scheme::
|
|
* Signing key storage::
|
|
* Denomination key storage::
|
|
* Auditor signature storage::
|
|
@end menu
|
|
|
|
@node Configuration format
|
|
@section Configuration format
|
|
|
|
|
|
In Taler realm, any component obeys to the same pattern to get configuration
|
|
values. According to this pattern, once the component has been installed, the
|
|
installation deploys default values in @cite{$@{prefix@}/share/taler/config.d/}, in
|
|
@cite{.conf} files. In order to override these defaults, the user can write a custom
|
|
@cite{.conf} file and either pass it to the component at execution time, or name it
|
|
@cite{taler.conf} and place it under @cite{$HOME/.config/}.
|
|
|
|
|
|
A config file is a text file containing @cite{sections}, and each section contains
|
|
its @cite{values}. The right format follows:
|
|
|
|
@example
|
|
[section1]
|
|
value1 = string
|
|
value2 = 23
|
|
|
|
[section2]
|
|
value21 = string
|
|
value22 = /path22
|
|
@end example
|
|
|
|
Throughout any configuration file, it is possible to use @code{$}-prefixed variables,
|
|
like @code{$VAR}, especially when they represent filesystem paths.
|
|
It is also possible to provide defaults values for those variables that are unset,
|
|
by using the following syntax: @code{$@{VAR:-default@}}.
|
|
However, there are two ways a user can set @code{$}-prefixable variables:
|
|
|
|
by defining them under a @code{[paths]} section, see example below,
|
|
|
|
@example
|
|
[paths]
|
|
TALER_DEPLOYMENT_SHARED = $@{HOME@}/shared-data
|
|
..
|
|
[section-x]
|
|
path-x = $@{TALER_DEPLOYMENT_SHARED@}/x
|
|
@end example
|
|
|
|
or by setting them in the environment:
|
|
|
|
@example
|
|
$ export VAR=/x
|
|
@end example
|
|
|
|
The configuration loader will give precedence to variables set under @code{[path]},
|
|
though.
|
|
|
|
The utility @code{taler-config}, which gets installed along with the exchange, serves
|
|
to get and set configuration values without directly editing the @cite{.conf}.
|
|
The option @code{-f} is particularly useful to resolve pathnames, when they use
|
|
several levels of @code{$}-expanded variables. See @code{taler-config --help}.
|
|
|
|
Note that, in this stage of development, the file @code{$HOME/.config/taler.conf}
|
|
can contain sections for @emph{all} the component. For example, both an exchange and
|
|
a bank can read values from it.
|
|
|
|
The repository @code{git://taler.net/deployment} contains examples of configuration
|
|
file used in our demos. See under @code{deployment/config}.
|
|
|
|
@cartouche
|
|
@quotation Note
|
|
Expectably, some components will not work just by using default values, as their
|
|
work is often interdependent. For example, a merchant needs to know an exchange
|
|
URL, or a database name.
|
|
@end quotation
|
|
@end cartouche
|
|
|
|
|
|
|
|
@node Reserve management
|
|
@section Reserve management
|
|
|
|
|
|
Incoming transactions to the exchange's provider result in the
|
|
creation or update of reserves, identified by their reserve key. The
|
|
command line tool @cite{taler-exchange-reservemod} allows create and
|
|
add money to reserves in the exchange's database.
|
|
|
|
|
|
|
|
|
|
@node Database Scheme
|
|
@section Database Scheme
|
|
|
|
|
|
The exchange database must be initialized using @cite{taler-exchange-dbinit}. This
|
|
tool creates the tables required by the Taler exchange to operate. The
|
|
tool also allows you to reset the Taler exchange database, which is useful
|
|
for test cases but should never be used in production. Finally,
|
|
@cite{taler-exchange-dbinit} has a function to garbage collect a database,
|
|
allowing administrators to purge records that are no longer required.
|
|
|
|
The database scheme used by the exchange look as follows:
|
|
|
|
@image{exchange-db,5in,,,png}
|
|
|
|
|
|
@node Signing key storage
|
|
@section Signing key storage
|
|
|
|
|
|
The private online signing keys of the exchange are stored in a
|
|
subdirectory "signkeys/" of the "KEYDIR" which is an option in the
|
|
"[exchange]" section of the configuration file. The filename is the
|
|
starting time at which the signing key can be used in microseconds
|
|
since the Epoch. The file format is defined by the @cite{struct TALER_EXCHANGEDB_PrivateSigningKeyInformationP}:
|
|
|
|
@example
|
|
struct TALER_EXCHANGEDB_PrivateSigningKeyInformationP @{
|
|
struct TALER_ExchangePrivateKeyP signkey_priv;
|
|
struct TALER_ExchangeSigningKeyValidityPS issue;
|
|
@};
|
|
@end example
|
|
|
|
|
|
@node Denomination key storage
|
|
@section Denomination key storage
|
|
|
|
The private denomination keys of the exchange are store in a
|
|
subdirectory "denomkeys/" of the "KEYDIR" which is an option in the
|
|
"[exchange]" section of the configuration file. "denomkeys/" contains
|
|
further subdirectories, one per denomination. The specific name of
|
|
the subdirectory under "denomkeys/" is ignored by the exchange.
|
|
However, the name is important for the "taler-exchange-keyup" tool
|
|
that generates the keys. The tool combines a human-readable encoding
|
|
of the denomination (i.e. for EUR:1.50 the prefix would be
|
|
"EUR_1_5-", or for EUR:0.01 the name would be "EUR_0_01-") with a
|
|
postfix that is a truncated Crockford32 encoded hash of the various
|
|
attributes of the denomination key (relative validity periods, fee
|
|
structure and key size). Thus, if any attributes of a coin change,
|
|
the name of the subdirectory will also change, even if the
|
|
denomination remains the same.
|
|
|
|
Within this subdirectory, each file represents a particular
|
|
denomination key. The filename is the starting time at which the
|
|
signing key can be used in microseconds since the Epoch. The
|
|
format on disk begins with a
|
|
@cite{struct TALER_EXCHANGEDB_DenominationKeyInformationP} giving
|
|
the attributes of the denomination key and the associated
|
|
signature with the exchange's long-term offline key:
|
|
|
|
@example
|
|
struct TALER_EXCHANGEDB_DenominationKeyInformationP @{
|
|
struct TALER_MasterSignatureP signature;
|
|
struct TALER_DenominationKeyValidityPS properties;
|
|
@};
|
|
@end example
|
|
|
|
This is then followed by the variable-size RSA private key in
|
|
libgcrypt's S-expression format, which can be decoded using
|
|
@cite{GNUNET_CRYPTO_rsa_private_key_decode()}.
|
|
|
|
@menu
|
|
* Revocations::
|
|
@end menu
|
|
|
|
@node Revocations
|
|
@subsection Revocations
|
|
|
|
@cindex payback
|
|
@cindex revocation
|
|
When an exchange goes out of business or detects that the private
|
|
key of a denomination key pair has been compromised, it may revoke
|
|
some or all of its denomination keys. At this point, the hashes
|
|
of the revoked keys must be returned as part of the @code{/keys} response
|
|
under ``payback''. Wallets detect this, and then return unspent
|
|
coins of the respective denomination key using the @code{/payback}
|
|
API.
|
|
|
|
When a denomination key is revoked, a revocation file is placed
|
|
into the respective subdirectory of ``denomkeys/''. The file has the
|
|
same prefix as the file that stores the
|
|
@cite{struct TALER_EXCHANGEDB_DenominationKeyInformationP} information,
|
|
but is followed by the ``.rev'' suffix. It contains a 64-byte
|
|
EdDSA signature made with the master key of the exchange with purpose
|
|
@code{TALER_SIGNATURE_MASTER_DENOMINATION_KEY_REVOKED}. If such a file
|
|
is present, the exchange must check the signature and if it is valid
|
|
treat the respective denomination key as revoked.
|
|
|
|
Revocation files can be generated using the
|
|
@code{taler-exchange-keyup} command-line tool using the @code{-r}
|
|
option. The Taler auditor will instruct operators to generate
|
|
revocations if it detects a key compromise (which is possible more
|
|
coins of a particular denomination were deposited than issued).
|
|
|
|
It should be noted that denomination key revocations should only happen
|
|
under highly unusual (``emergency'') conditions and not under normal
|
|
conditions.
|
|
|
|
|
|
@node Auditor signature storage
|
|
@section Auditor signature storage
|
|
|
|
|
|
Signatures from auditors are stored in the directory specified
|
|
in the exchange configuration section "exchangedb" under the
|
|
option "AUDITOR_BASE_DIR". The exchange does not care about
|
|
the specific names of the files in this directory.
|
|
|
|
Each file must contain a header with the public key information
|
|
of the auditor, the master public key of the exchange, and
|
|
the number of signed denomination keys:
|
|
|
|
@example
|
|
struct AuditorFileHeaderP @{
|
|
struct TALER_AuditorPublicKeyP apub;
|
|
struct TALER_MasterPublicKeyP mpub;
|
|
uint32_t dki_len;
|
|
@};
|
|
@end example
|
|
|
|
This is then followed by @cite{dki_len} signatures of the auditor of type
|
|
@cite{struct TALER_AuditorSignatureP}, which are then followed by another
|
|
@cite{dki_len} blocks of type @cite{struct TALER_DenominationKeyValidityPS}.
|
|
The auditor's signatures must be signatures over the information of
|
|
the corresponding denomination key validity structures embedded in a
|
|
@cite{struct TALER_ExchangeKeyValidityPS} structure using the
|
|
@cite{TALER_SIGNATURE_AUDITOR_EXCHANGE_KEYS} purpose.
|
|
|
|
|
|
|
|
@c **********************************************************
|
|
@c ******************* Appendices *************************
|
|
@c **********************************************************
|
|
|
|
@node GNU-AGPL
|
|
@chapter GNU Affero GPL
|
|
@cindex license
|
|
@include agpl.texi
|
|
|
|
@node GNU-FDL
|
|
@chapter GNU Free Documentation License
|
|
@cindex license
|
|
@include fdl-1.3.texi
|
|
|
|
@node Concept Index
|
|
@chapter Concept Index
|
|
|
|
@printindex cp
|
|
|
|
@bye
|