\title{Taler: Usable, privacy-preserving payments for the Web} \date{\today} %\documentclass[twoside,letterpaper]{IEEEtran} \documentclass{IEEEtran} \usepackage[margin=1in]{geometry} \usepackage[utf8]{inputenc} \usepackage{url} \usepackage{tikz} \usepackage{eurosym} \usepackage{listings} \usepackage{graphicx} %\usepackage{wrapfig} %\usepackage{caption} \usepackage{subcaption} \usepackage{url} %\usepackage{stfloats} \usetikzlibrary{shapes,arrows} \usetikzlibrary{positioning} \usetikzlibrary{calc} \begin{document} % Not sure how to do authors with the % IEEEtran template correctly ... \author{ \IEEEauthorblockN{Jeffrey Burdges, Christian Grothoff, Florian Dold, Marcello Stanisci} \\ \IEEEauthorblockA{ Inria Rennes - Bretagne Atlantique\\ Email: FIRSTNAME.LASTNAME@inria.fr } } \maketitle \begin{abstract} Taler is a new electronic online payment system which provides anonymity for customers and, due to this design choice, also offers significantly better usability. This paper first describes the interaction processes of online payment systems, and analytically compares their usability for both customers and merchants. We then focus on the resulting assurances that Taler provides, as---particularly for payment systems---usability and security are intertwined. Web payment systems must also face the reality of constraints imposed by modern Web browser security architecture, so the analysis includes considerations of how Web payment systems exploit the security infrastructure provided by the modern Web. \end{abstract} \section{Introduction} The Internet needs a secure, usable and privacy-preserving micropayment system, which is not backed by a ``crypto currency''. Payment systems involving state-issued currencies have been used for centuries to facilitate transactions, and the involvement of the state has been critical as state institutions can dampen fluctuations in the value of the currency.~\cite{dominguez1993} Controlling money supply is critical to ensure stable prices that facilitate trade~\cite{quantitytheory1997volckart} instead of speculation~\cite{lewis_btc_is_junk}. As Internet transactions, such as sending an e-mail or reading a Web site, tend to be of smaller value than traditional transactions involving the exchange of physical goods, we are faced with the challenge of reducing the mental and technical overheads of existing payment systems to handle these micropayments. Addressing this problem is urgent: ad-blocking technology is eroding advertising as a substitute for micropayments~\cite{adblockblocks}, and the Big Data business model in which citizens pay with their private information~\cite{ehrenberg2014data} in combination with the deep state hastens our society's regression towards post-democracy~\cite{rms2013democracy}. The focus of this paper is Taler, a new free software payment system designed to meet certain key ethical considerations. In Taler, the customer remains anonymous while the merchant is taxable. Here, anonymous simply means that the payment system does not require any personal information from the customer, and that different transactions by the same customer are unlinkable. Naturally, the specifics of the transaction---such as delivery of goods to a shipping address, or the use of non-anonymous IP-based communication---may still leak information about the customer's identity. {\em Taxable} means that the state can obtain the necessary information about the contract to levy income, sales, or value-added taxes. Taler uses blind signatures~\cite{chaum1983blind} to create digital coins, and a new {\em refresh} protocol to allow giving change and refunds while maintaining unlinkability. This paper will not consider the details of Taler's cryptographic protocols\footnote{Details of the protocol are documented at \url{https://api.taler.net/}} and instead focuses on how a modern payment system using blind signatures could practically be integrated with the modern Web. This includes the challenge of hiding the cryptography from the users. Our goal is to show that existing {\em mental models} users have from existing widespread payment systems apply naturally to Taler. Key contributions of this paper are: \begin{itemize} \item A description of different payment systems using common terminology, which allows us to analytically compare these systems with respect to security and usability. \item An introduction to the Taler payment system from the perspective of users and merchants, with a focus on how to achieve secure payments in a way that is intuitive and has adequate fail-safes. \item Detailed considerations for how to adapt Taler to Web payments and the intricacies of securing payments within the constraints of modern browsers. \item A publicly available free software reference implementation of the proposed architecture. \end{itemize} \section{Existing payment workflows} Before we look at the payment workflow for Taler, we sketch the workflow of existing payment systems. This establishes a common terminology which we will use to compare different payment processes, and crucially also provide an indication as to how we can relate Taler's workflow to existing {\em mental models} that users already have. Detailed interaction diagrams for some of the payment systems discussed here can be found in the Appendix. \subsection{Cash} Cash has traditionally circulated by being passed directly from buyers to sellers with each seller then becoming a buyer. Thus, cash is inherently a {\em peer-to-peer} payment system as participants all appear in the both buyer and seller roles, just at different times. However, this view is both simplified and somewhat dated. In today's practice, cash is frequently first {\em withdrawn} from ATMs by customers who then {\em spend} it with merchants, who, in turn, {\em deposit} the cash with their respective {\em bank}. In this flow, security is achieved as the customer {\em authenticates} to the ATM using {\em credentials} provided by the customer's bank, and the merchant specifies his {\em account} details when depositing the cash. The customer does not authenticate when spending the cash, but the merchant {\em validates} the authenticity of the {\em coins} or bills. Coins and bills are {\em minted} by state-licensed institutions, such as the US Mint. These institutions also provide detailed instructions for how to validate the authenticity of the coins or bills~\cite{ezb2016ourmoney}, and are typically the final trusted authority on the authenticity of coins and bills. As customers need not authenticate, purchases remain {\em anonymous}, modulo the limited tracking enabled by serial numbers printed on bills~\cite{pets2004kuegler}. % NOTE : Internet claims this does not happen, but no references. % https://rocketatm.com/notice-_recorded_serial_numbers_atm_decal Spending cash does not provide any inherent {\em proof of purchase} for the customer. Instead, the merchant provides paper {\em receipts}, which are generated independently and do not receive the same anti-forgery protections that are in place for cash. Against most attacks, customers and merchants limit their risks to the amount of cash that they carry or accept at a given time~\cite{Bankrate}. Additionally, customers are advised to choose the ATMs they use carefully, as malicious ATMs may attempt to steal their customer's credentials. Authentication with an ATM can involve a special ATM card, or, more commonly, the use of credit or debit cards. In all these cases, these physical security tokens are issued by the customer's bank. % \smallskip \subsection{Credit and debit cards} Credit and debit card payments operate by the customer providing their credentials to the merchant. Many different authentication and authorization schemes are in use in various combinations including both secret information, which are usually PINs, and physical security devices such as TANs~\cite{kobil2016tan}, cards with an EMV chip~\cite{emv}, and the customer's mobile phone~\cite{mtan}. A typical modern Web payment process involves: {(1.)} the merchant offering a secure communication channel using TLS based on the X.509 public key infrastructure;\footnote{Given numerous TLS protocol and implementation flaws as well as X.509 key management incidents in recent years~\cite{holz2014}, the security provided by TLS is at best questionable.} {(2.)} selecting a {\em payment method}; {(3.)} entering the credit card details like owner's name, card number, expiration time, CVV code, and billing address; and {(4.)} (optionally) authorizing the transaction via mobile TAN, or by authenticating against the customer's bank, often on a Web site that is operated by the payment processor and {\em not} the customer's bank. Figure~\ref{fig:cc3ds} in the % FIXME why "..on the Web today using.." and not just "..on the Web using.." Appendix shows a typical card-based payment process on the Web today using the UML style of the W3c payment interest group~\cite{pigs}. Most of the details are not relevant to this paper, but the diagram nicely illustrates the complexity of the common 3-D secure (3DS) process. Given this process, there is an inherent risk of information leakage of customers' credentials. Fraud detection systems attempt to detect misuse of leaked credentials, and payment system providers handle disputes between customers and merchants. As a result, Web payment processes may finish with {(5.)} the payment being rejected for a variety of reasons, such as false positives in fraud detection or the merchant not accepting the particular card issuer. Traditionally, merchants bear most of the financial risk, and a key ``feature'' of the 3DS process compared to traditional card payments is to shift dispute liability to the issuer of the card who may then shift it to the customer. % % online vs offline vs swipe vs chip vs NFC ??? % extended verification % Even in cases where the issuer or the merchant remains legally first in line, there are still risks customers incur from the card dispute procedures, such as neither them nor the payment processor noticing fraudulent transactions, or them noticing fraudulent transactions past the date at which their bank will refund them. The customer also typically only has a merchant-generated comment and the amount paid in his credit card statement as a proof for the transaction. Thus, the use of credit cards online does not generate any verifiable electronic receipts for the customers, which enables malicious merchants to later change the terms of the contract. Beyond these issues, customers face secondary risks of identity theft from the personal details exposed by the authentication procedures. In this case, even if the financial damages are ultimately covered by the bank, the customer always has to deal with the hassle of notifying the bank in the first place. As a result, customers must remain wary about using their card, which limits their online shopping~\cite[p. 50]{ibi2014}. % There is nevertheless a trend towards customers preferring cards % over cash even in face-to-face purchases \cite{} in part because % cash theft can be violent even if the amounts as stake are smaller % than with electronic theft. % %Merchants are exposed to these same risks because either laws and/or %contracts with the payment system providers require them to take care %in handling customer information. % 40 million stolen at target. fine? %In cash payments, these risks do not exist because customers have %complete control over the authentication procedure with their bank %and the merchant is not involved. % pressure to shop with big merchants % merchants keep payment credentials on file % Just a few merchants like Apple demand credentials up front % "this reversal of authentication vs shopping slows shopping" % \smallskip \subsection{Bitcoin} Bitcoin operates by recording all transactions in a pseu\-do\-ny\-mous public {\em ledger}. A Bitcoin account is identified by its public key, and the owner must know the corresponding private key to authorize the transfer of Bitcoins from the account to other accounts. The information in the global public ledger allows everybody to compute the balances in all accounts and to see all transactions. Transactions are denominated in a new currency labeled BTC, whose valuation depends upon speculation. Adding transactions to the global public ledger involves broadcasting the transaction data, peers verifying and appending it to the public ledger, and some peer in the network solving a moderately hard computational proof-of-work puzzle, which is called {\em mining}. The mining process is incentivised by transaction fees and mining rewards. The latter process is also what provides initial accumulation for BTC.~\cite{nakamoto2008bitcoin} Conversion to BTC from other currencies and vice versa incurs substantial fees~\cite{BTCfees}. There is now an extreme diversity of Bitcoin-related payment technologies, but usability improvements are usually achieved by adding a trusted third party, and there have been many incidents where such parties then embezzled funds from their customers~\cite{BTC:demise}. The classical Bitcoin payment workflow consisted of entering payment details into a peer-to-peer application. The user would access their Bitcoin {\em wallet} and instruct it to transfer a particular amount from one of his accounts to the account of the merchant. He could possibly include additional metadata to be associated with the transfer and embedded into the global public ledger. % Technically the following is not true, there are % wallets that run purely in the browser and store % the keys locally: https://github.com/frozeman/bitcoin-browser-wallet The wallet application would then transmit the request to the Bitcoin peer-to-peer overlay network. The use of an external payment application makes wallet-based payments significantly less browser-friendly than ordinary card payments, as illustrated in Figure~\ref{fig:bitcoin} in the Appendix. Bitcoin payments are only confirmed when they appear in the public ledger, which is updated at an average frequency of once every 10 minutes. Even then, it is possible that a fork in the so-called block chain may void durability of the transaction~\cite{nakamoto2008bitcoin}. As a result, customers and merchants must either accommodate this delay, or incur fraud risks during this indeterminate period. Bitcoin is considered to be secure against an adversary who cannot control around a fifth of the Bitcoin miner's computational resources~\cite{BTC:Bahack13,BTC:MajorityNotEnough,BTC:Eclipse}. % 21percent? As a result, the network must expend considerable computational resources to keep this value high. According to~\cite{vice_btc_unsustainable}, a single Bitcoin transaction uses roughly enough electricity to power 1.57 American households for a day. These costs are largely hidden by speculation in BTC, but that speculation itself contributes to BTC being unstable.~\cite{jeffries_economists_v_btc,lehmann_btc_fools_gold,lewis_btc_is_junk}. % exacerbating risk % fees hit you 2-3 times with currency conversions % more on massive transaction fees from blockchain.info There are several examples of Bitcoin's pseudononymity being broken by investigators~\cite{BTC:Anonymity}. This has resulted in the development of new protocols with better privacy protections. Zerocoin \cite{miers2013zerocoin} is such an extension of Bitcoin: It affords protection against linkability of transactions, but at non-trivial additional computational costs even for spending coins. This currently makes using Zerocoin unattractive for payments with mobile devices. % Bitcoin's pseudononymity applies equally to both customers and merchants, which makes Bitcoin amen\-able to tax evasion, money laundering, and sales of contraband. As a result, anonymity tools like mixnets do not enjoy particularly widespread support in the Bitcoin community where many participants seek to make the currency appear more legitimate. % In addition, the Bitcoin protocol does not interact well with % conventional anonymity networks like Tor \cite{BTC:vsTor} % dark pools? % mining suck0rs, % DDoS : wired article? % economic ideology \subsection{Walled garden payment systems} Walled garden payment systems offer ease of use by processing payments using a trusted payment service provider. Here, the customer authenticates to the trusted service, and instructs the payment provider to execute a transaction on his behalf (see Figure~\ref{fig:paypal}). In these payment systems, the provider basically acts like a bank with accounts carrying balances for the various users. In contrast to traditional banking systems, both customers and merchants are forced to have an account with the same provider. Each user must take the effort to establish his identity with a service provider to create an account. Merchants and customers obtain the best interoperability in return for their account creation efforts if they start with the biggest providers. As a result, there are a few dominating walled garden providers, with AliPay, ApplePay, GooglePay, SamsungPay and PayPal being the current oligopoly. In this paper, we will use PayPal as a representative example for our discussion of these payment systems. As with card payment systems, these oligopolies are politically dangerous~\cite{crinkey2011rundle}, and the lack of competition can result in excessive profit taking that may require political solutions~\cite{guardian2015cap} to the resulting market failure. The use of non-standard proprietary interfaces to the payment processing service of these providers serves to reinforce the customer lock-in. \section{Taler} Taler is a free software cryptographic payment system. It has an open protocol specification, which couples cash-like anonymity for customers with low transaction costs, signed digital receipts, and accurate income information to facilitate taxation and anti-corruption efforts. % FIXME: maybe say what blind signature are Taler achieves anonymity for buyers using {\em blind signatures}~\cite{chaum1983blind}. Since their discovery thirty years ago, cryptographers have viewed blind signatures as the optimal cryptographic primitive for consumer-level transaction systems. However, previous transaction systems based on blind signatures have failed to see widespread adoption. This paper details strategies for hiding the cryptography from users and integrating smoothly with the Web, thereby providing crucial steps to bridge the gap between good cryptography and real-world deployment. %\subsection{Design overview} \begin{figure}[b!] \centering \begin{tikzpicture} \tikzstyle{def} = [node distance=3em and 5em, inner sep=1em, outer sep=.3em]; \node (origin) at (0,0) {}; \node (exchange) [def,above=of origin,draw]{Exchange}; \node (customer) [def, draw, below left=of origin] {Customer}; \node (merchant) [def, draw, below right=of origin] {Merchant}; \node (auditor) [def, draw, above right=of origin]{Auditor}; \tikzstyle{C} = [color=black, line width=1pt] \draw [<-, C] (customer) -- (exchange) node [midway, above, sloped] (TextNode) {withdraw coins}; \draw [<-, C] (exchange) -- (merchant) node [midway, above, sloped] (TextNode) {deposit coins}; \draw [<-, C] (merchant) -- (customer) node [midway, above, sloped] (TextNode) {spend coins}; \draw [<-, C] (exchange) -- (auditor) node [midway, above, sloped] (TextNode) {verify}; \end{tikzpicture} \caption{Taler system overview.} \label{fig:system} \end{figure} There are four components of the Taler system (Figure~\ref{fig:system}): \begin{itemize} \item {\em Customers} use a digital wallet to withdraw, hold, and spend coins. Wallets also manage the customer's accounts at the exchange, and keep receipts in a transaction history. Wallets can be realized as browser extensions, mobile Apps or even in custom hardware. If a user's digital wallet is compromised, the current balance may be lost just like with an ordinary wallet for cash. \item {\em Exchanges}, which are run by financial service providers, enable customers to withdraw anonymous digital coins, and merchants to deposit digital coins, in exchange for bank money. Coins are signed by the exchange using a blind signing scheme~\cite{chaum1983blind}. Thus, only the exchange can issue new coins, but coins can't be traced back to the customer that withdrew them. Furthermore, exchanges learn the amounts withdrawn by customers and deposited by merchants, but they do not learn the relationship between customers and merchants. Exchanges perform online detection of double spending, thus providing merchants instant feedback ---including digital proofs---in case of misbehaving customers. \item {\em Merchants} provide goods or services in exchange for coins held by customers' wallets. Merchants deposit these coins at the exchange for their regular currency value. Merchants consist of a {\em frontend}, which interacts with the customer's wallet, and a {\em backend}, which interacts with the exchange. Typical frontends include Web shops and point-of-sale systems. \item {\em Auditors} verify that exchanges operate correctly to limit the risk that customers and merchants incur by using a particular exchange. Auditors are typically operated by financial regulatory authorities. Depending on local legislation, auditors mandate that exchanges have enough financial reserves before authorizing them to create a given volume of signed digital coins in order to compensate for potential risks due to operational failures (such as data loss or theft of private keys) of the exchange. \end{itemize} The specific protocol between wallet and merchant depends on the setting. For a traditional store, a near field communication (NFC) protocol might be used between a point-of-sale system and a mobile application. In this paper, we focus on Web payments for an online shop. \begin{figure*} \includegraphics[width=0.9\textwidth]{figs/taler-withdraw.pdf} \caption{Withdrawing coins with Taler.} \label{fig:taler-withdraw} \end{figure*} % \smallskip \subsection{Web payment workflow} In this section, we explain how the actors in the Taler system interact by way of a typical payment. Initially, the customer installs the Taler wallet extension for their browser. This only needs to be done once per browser. Naturally, this step may become superfluous if Taler is integrated tightly with browsers in the future. Regardless, installing the extension involves one or two clicks to confirm the operation. Restarting the browser is not required. \paragraph{Withdrawing coins} As with cash, the customer must first withdraw digital coins (Figure~\ref{fig:taler-withdraw}). For this, the customer must first visit the bank's online portal. Here, the bank will typically require some form of authentication, the specific method used depends on the bank (Figure~\ref{subfig:login}). \begin{figure} \begin{subfigure}{\linewidth} \includegraphics[width=\linewidth]{figs/bank0a.png} \caption{Bank login. (Simplified for demonstration.)} \label{subfig:login} \end{subfigure} \begin{subfigure}{\linewidth} \includegraphics[width=\linewidth]{figs/bank1a.png} \caption{Specify amount to withdraw. (Integrated bank support.)} \label{subfig:withdraw} \end{subfigure} \begin{subfigure}{\linewidth} \includegraphics[width=\linewidth]{figs/bank2a.png} \caption{Select exchange provider. (Generated by wallet.)} \label{subfig:exchange} \end{subfigure} \begin{subfigure}{\linewidth} \includegraphics[width=\linewidth]{figs/bank3a.png} \caption{Confirm transaction with a PIN. (Generated by bank.)} \label{subfig:pin} \end{subfigure} \caption{Required steps in a Taler withdrawal process.} \label{fig:withdrawal} \end{figure} The next step depends on the level of Taler support offered by the bank: \begin{itemize} \item If the bank does not offer integration with Taler, the customer needs to use the menu of the wallet to create a {\em reserve}. The wallet will ask which amount in which {\em currency} (e.g. EUR or USD) the customer wants to withdraw, and allow the customer to select an exchange. Given this information, the wallet will instruct the customer to transfer the respective amount to the account of the exchange. The customer will have to enter a % FIXME it is not said that this crypto token is the reserve, % or, more abstractly, that "identify" this operation % CG: I don't think this has to be said. 54-character reserve key, which includes 256 bits of entropy and an 8-bit checksum into the transfer subject. Naturally, the above is exactly the kind of interaction we would like to avoid for usability reason. \item Hence, if the bank fully supports Taler, the customer has a form in the online banking portal in which they can specify an amount to withdraw (Figure~\ref{subfig:withdraw}). The bank then triggers an interaction with the wallet to allow the customer to select an exchange (Figure~\ref{subfig:exchange}). Afterwards, the wallet instructs the bank about the details of the wire transfer. The bank asks the customer to authorize the transfer, and finally confirms to the wallet that the transfer has been successfully initiated. \end{itemize} In either case, the wallet can then withdraw the coins from the exchange, and does so in the background without further interaction with the customer. In principle, the exchange can be directly operated by the bank, in which case the step where the customer selects an exchange could be skipped by default. However, we generally assume that the exchange is a separate entity, as this yields the largest anonymity set for customers, and may help create a competitive market. \paragraph{Spending coins} % \tinyskip \begin{figure*} \includegraphics[width=0.9\textwidth]{figs/taler-pay.pdf} \caption{Payment processing with Taler.} \label{fig:taler-pay} \end{figure*} \begin{figure}[b!] \begin{subfigure}[H]{0.5\textwidth} \includegraphics[width=\textwidth]{figs/cart.png} \caption{Select article. (Generated by Web shop.)} \label{subfig:cart} \end{subfigure} \begin{subfigure}{0.5\textwidth} \includegraphics[width=\textwidth]{figs/pay.png} \caption{Confirm payment. (Generated by Taler wallet.)} \label{subfig:payment} \end{subfigure} \begin{subfigure}{0.5\textwidth} \includegraphics[width=\textwidth]{figs/fulfillment.png} \caption{Receive article. (Generated by Web shop.)} \label{subfig:fulfillment} \end{subfigure} \caption{Required steps in a Taler checkout process.} \label{fig:shopping} \end{figure} At a later point in time, the customer can spend their coins by visiting a merchant that accepts digital coins in the respective currency issued by the respective exchange (Figure~\ref{fig:taler-pay}). Merchants are generally configured to either accept a specific exchange, or to accept all the exchanges audited by a particular auditor. Merchants can also set a ceiling for the maximum amount of transaction fees they are willing to cover. Usually these details do not matter for the customer, as we expect most merchants to allow most accredited exchange providers, and for exchanges to operate with transaction fees acceptable to most merchants. If transaction fees are higher than what is covered by the merchant, the customer may choose to cover them. As with traditional Web transactions, customers first select which items they wish to buy. This can involve building a traditional shopping cart, or simply clicking on a particular link for the respective article (Figure~\ref{subfig:cart}). As with card payments, the Web shop may then allow the customer to select a payment method, including Taler. Taler also allows the Web shop to detect the presence of a Taler wallet (Figure~\ref{listing:presence}), so that this step may be skipped (as it is in Figure~\ref{fig:shopping}). If Taler was detected or selected, the Web shop sends a digitally signed {\em contract proposal} to the wallet extension (Figure~\ref{listing:contract}). The wallet then presents the contract to the user. The format of the contract is in an extensible JSON-based format defined by Taler and not HTML, as the rendering of the contract is done by the wallet to ensure correct visual representation. In case the transaction fees need to be covered by the customer, these are shown together with the rest of the proposed contract. If the customer approves the contract by clicking the ``Confirm Payment'' button (Figure~\ref{subfig:payment}), their wallet signs the contract with enough coins to cover the contract's cost, stores all of the information in its local database, and redirects the browser to a {\em fulfillment} URL provided by the merchant (Figure~\ref{subfig:fulfillment}). % FIXME: technically this is not entirely true, if you % allow CORS ... The wallet cannot directly send the payment to the merchant, as the page showing the contract is provided as a background page controlled by the Web Extension\footnote{\url{https://developer.chrome.com/extensions}} and thus submitting coins from the background would not use the HTTP-context that the Web shop's page requires for session management. % % FIXME: can we do better with the description? Instead, the server-side of the fulfillment page usually first detects that the contract has not yet been paid by checking the merchant's local database and the HTTP session state. {\bf (A)} If the state indicates that this customer did not yet pay, the merchant generates a page that shows the customer an indication that the payment is being processed, and tries to interact with the wallet, requesting payment. If the wallet is not detected after a few milliseconds, the page transitions to the card payment process. If the wallet is present, the page requests payment from the wallet. The wallet then determines that the customer already confirmed the payment and immediately transfers the coins to the JavaScript logic of the fulfillment page. The fulfillment page then transfers the coins to the merchant usually using an asynchronous HTTP POST request. The request is controlled by the merchant's JavaScript and not by the wallet. This ensures that the merchant is in full control of the communication between the merchant's server and the client-side scripts interacting with the merchant's server. The interactions with the wallet are thus purely local interactions within the browser. Upon receipt of the payment information, the merchant confirms the payment with the exchange, marks the payment as received, and notifies the JavaScript on the client side of the result. \begin{itemize} \item If the payment fails on the network, the request is typically retried. How often the client retries automatically before informing the user of the network issue is up to the merchant. If the network % FIXME this (above) could be ambiguous because the network failure % can happen between the wallet and the merchant without the merchant % getting any (failing) request, so the merchant cannot count how much % times a payment has failed. % CG: Well, the merchant can do that counting *client-side*. The retries % will be controlled by the JS on the client side, which is provided % by the merchant initially. failure persists and is between the customer and the merchant, the wallet will try to recover control over the coins at the exchange by effectively spending the coins first using Taler's % FIXME(dold): Do we properly introduce/discuss refreshing before? refresh protocol. In this case, later deposits by the merchant will simply fail. If the merchant already succeeded with the payment before the network failure, the customer can either retry the operation via the transaction history, or demand a refund (see below). Handling these errors does not require the customer to give up his privacy. \item If the payment fails due to the exchange claiming that the request was invalid, the diagnostics created by the exchange are passed to the wallet for inspection. The wallet then decides whether the exchange was correct, and can then inform the user about a fraudulent or buggy exchange. At this time, it allows the user to export the relevant cryptographic data to be used in court. If the exchange's proofs were correct and coins were double-spent, the wallet informs the user that its database must have % FIXME what about giving an example of an out-of-date DB? Put in % this way, it appears that Taler has viable ways to fail. In other % words, that it's normal to get such a failure. Instead, that failure % can occur due to coins not spent for *years* (or some other corner case), % that saves Taler from being "blamed" been out-of-date, updates the database and allows the user to retry the transaction. \item If the payment succeeded, the JavaScript on the client side triggers effectively a ``reload'' of the fulfillment page, triggering case (B) detailed below. \end{itemize} {\bf (B)} Upon subsequent visits, the server detects that the payment has already been processed and directly generates a fulfillment page either confirming the payment, or---in the case of payments for a digital article---transmits the digital artifact to the client. \subsection{Bookmarks and deep links} Taler's architecture also enables smooth use of payment URIs on the contemporary Web. In particular, we need to consider the possibility that a user may bookmark the fulfillment page, or forward a link to the fulfillment page to another user. The given design supports {\em bookmarking}. If the merchant's session management is still tracking the user when he returns via the bookmark, the page generation detects that the user has already paid and serves the final fulfillment page. If the session has been lost, the merchant will generate a fulfillment page asking for payment. In this case, the wallet will detect that it has already paid this contract via a unique identifier in the contract, and will automatically re-play the payment. The merchant confirms that this customer already paid, and generates the final fullfilment page that the user has previously payed for (and seen). All this still appears as instantaneous to the user as it merely adds a few extra network round trips. In contrast, if the customer sends a link to the fulfillment page to another user, thereby possibly sharing a {\em deep link} into the merchant's shop, the other customer's wallet will fail to find an existing payment. Consequently, the fulfillment page will not receive the payment details and instead provide the user with the proposed contract which contains a description of the item previously bought by the other user. The recipient of the link can then decide to also purchase the item. The design, in particular POSTing the coins asyn\-chro\-nous\-ly from JavaScript, also ensures that the user can freely navigate with the back and forward buttons. As all requests from all HTTP(S) URIs ever seen by the user in the browser are fetched via HTTP GET, they can be bookmarked, shared and safely reloaded. For caching, the merchant needs to ensure that the fulfillment page generated in case (A) is not cached by the browser, and in case (B) is not cached in the network. As an aside, the different pages of the merchant have clear delineations: the shopping pages conclude by proposing a contract, and the fulfillment page begins with processing an accepted contract. It is thus possible for these pages to be managed by separate parties. The control of the fulfillment page over the transmission of the payment information minimizes the need for exceptions to handle cross-origin resource sharing~\cite{rfc6454,cors}. % FIXME: for the above: add figures with code samples! % \smallskip \subsection{Giving change and refunds} % FIXME: maybe leave out change entirely? An important technical difference between Taler and previous transaction systems based on blind signing is that Taler is able to provide unlinkable change and refunds. From the user's point of view, obtaining change is automatic and handled by the wallet, i.e., if the user has a single coin worth \EUR{5} and wants to spend \EUR{2}, the wallet may request three \EUR{1} coins in change. Critically, the change giving process is completely hidden from the user. In fact, the graphical user interface does not offer a way to inspect the denominations of the various coins in the wallet, it only shows the total amount available in each denomination. Expanding the views to show details may show the exchange providers and fee structure, but not the cryptographic coins. Consequently, the major cryptographic advances of Taler are invisible to the user. Taler's technology also allows merchants to give refunds to customers. For this, the merchant merely has to send a signed message to the exchange confirming the refund, and notify the customer's wallet that the respective transaction was refunded. This can even be done with anonymous customers, as refunds are given as additional change to the owner of the coins that were originally spent to pay for the refunded transaction. Taler's protocol ensures unlinkability for both change and refunds, thereby assuring that the user has key conveniences of other payment systems while maintaining the security standard of an anonymous payment system. % Alternative version: %An important technical difference between Taler and previous %transaction systems based on blind signing is that in Taler coins %consist of a public-private key pair with the blind signature on the %public key, so that coins themselves can be used to anonymously sign %the purchase contract. % %An important technical difference between Taler and previous %transaction systems based on blind signing is that Taler coins %consist of a public-private key pair with the blind signature on the %public key, so that coins themselves can be used to anonymously sign %the purchase contract. % %In general, these coins exceed the cost of the contract, so the wallet %may specify that only a fraction of a coin be spent, leaving some %residual value on the partially spent coin as ``change''. % %As the merchant received only a signature of the coin, not private %or symmetric key material, merchants can refund anonymous coins by %asking the mint to restore a part of the coin's original value, %and notifying the customer's wallet to refresh the coin. % %Spending Taler coins reveals nothing about a customer per se. %Yet, any coins that hold value after being involved in a purchase or %a refund operation cannot be considered anonymous anymore because a %merchant, and possibly the exchange, has now seen them and could %link them that previous transaction. At best, these tainted coins %are only pseudononymous, similar to Bitcoin accounts. % %To maintain anonymity, a Taler wallet automatically performs a %{\em refresh} operation with the mint API to both replace tainted %coins with new freshly anonymized coins and to exchange old coins %before their denomination's expiration date. We view refreshing %partially spent coins as analogous to giving change in cash %transactions, but refreshing refunded coins allows Taler merchants %to refund anonymous customers. Cash transactions have these options, %but credit cards require customer identification for both operations. % Is this true? % no comment around randomizing the serial numbers on bills \subsection{NFC payments} We have so far focused on how Taler could be used for Web payments; however, Taler can also be naturally used over other protocols, such as near field communication (NFC). Here, the user would hold his NFC-enabled device running a wallet application near an NFC terminal to obtain the contract and confirm the payment on his device, which would then transfer the coins and obtain a receipt. An NFC application would be less restricted in its interaction with the point-of-sale system compared to a browser extension. Thus, running Taler over NFC is largely a simplification of the process. Specifically, there are no significant new concerns arising from an NFC device possibly losing contact with a point-of-sale system. For Web payments, Taler only employs idempotent operations to ensure coins are never lost, and that transactions adequately persist even in the case of network or endpoint failures. As a result, the NFC system can simply use the same transaction models to replay transmissions once contact with the point-of-sale system is reestablished. \subsection{Peer-to-peer payments} Peer-to-peer payments are possible with Taler as well; however, we need to distinguish two types of peer-to-peer payments. First, there is the {\em sharing} of coins among entities that mutually trust each other, for example within a family. Here, all users have to do is to export and import electronic coins over a secure channel, such as encrypted e-mail or via NFC. For NFC, the situation is straightforward because we presumably do not have to worry about man-in-the-middle attacks, while secure communication over the Internet is likely to remain a significant usability challenge. We note that sharing coins by copying the respective private keys across devices is not taxable: the exchange is not involved, no contracts are signed, and no records for taxation are created. However, the involved entities must trust each other, because after copying a private key both parties could spend the coins, but only the first transaction will succeed. Given this crucial limitation inherent in sharing keys, we consider it ethically acceptable that sharing is not taxable. Second, there is the {\em transactional} mutually exclusive transfer of ownership. This requires the receiving party to have a {\em reserve} with an exchange, and the exchanges would have to support wire transfers among them. If taxability is desired, the {\em reserve} would still need to be tied to a particular citizen's identity for tax purposes, and thus require similar identification protocols as commonly used for establishing a bank account. As such, in terms of institutions, one would expect this setup to be offered most easily by traditional banks. In terms of usability, transactional transfers are just as easy as sharing when performed over NFC, but more user friendly when performed over the Internet as they do not require a secure communication channel: the Taler protocol is by design still safe to use even if the communication is made over an unencrypted channel. Only the authenticity of the proposed contract needs to be assured. \subsection{Usability for merchants} Payment system security and usability is not only a concern for customers, but also for merchants. For consumers, existing schemes may be inconvenient and not provide privacy, but remembering to protect a physical token (e.g. the card) and to guard a secret (e.g. the PIN) is relatively straightforward. In contrast, merchants are expected to securely handle sensitive customer payment data on networked computing devices. However, securing computer systems---and especially payment systems that represent substantial value---is a hard challenge, as evidenced by large-scale break-ins with millions of consumer card records being illicitly copied~\cite{target}. Taler simplifies the deployment of a secure payment system for merchants. The high-level cryptographic design provides the first major advantage, as merchants never receive sensitive payment-related customer information. Thus, they do not have to be subjected to costly audits or certified hardware, as is commonly the case for processing card payments~\cite{pcidss}. In fact, the exchange does not need to have a formal business relationship with the shop at all. According to our design, the exchange's contract with the state regulator or auditor and the customers ought to state that it must honor all (legal and valid) deposits it receives. Hence, a merchant supplying a valid deposit request should be able to enforce this in court without a prior business agreement with the exchange. This dramatically simplifies setting up a shop to the point that the respective software only needs to be provided with the merchant's wire transfer routing information to become operational. Figure~\ref{listing:presence} shows how easy it is for a Web shop to detect the presence of a Taler wallet. The process requires a few cryptographic operations on the side of the merchant, such as signing a contract and verifying the customer's and the exchange's signatures. The merchant also needs to store transaction data as well as to match sales with incoming wire transfers from the exchange. Taler simplifies this for merchants by providing a generic payment processing {\em backend} for the Web shops. \begin{figure*}[h!] \begin{center} \begin{tikzpicture}[ font=\sffamily, every matrix/.style={ampersand replacement=\&,column sep=2cm,row sep=2cm}, source/.style={draw,thick,rounded corners,fill=green!20,inner sep=.3cm}, process/.style={draw,thick,circle,fill=blue!20}, sink/.style={source,fill=green!20}, datastore/.style={draw,very thick,shape=datastore,inner sep=.3cm}, dots/.style={gray,scale=2}, to/.style={->,>=stealth',shorten >=1pt,semithick,font=\sffamily\footnotesize}, every node/.style={align=center}] % Position the nodes using a matrix layout \matrix{ \node[source] (wallet) {Wallet}; \& \node[process] (browser) {Browser}; \& \node[process] (shop) {Web shop}; \& \node[sink] (backend) {Taler backend}; \\ }; % Draw the arrows between the nodes and label them. \draw[to] (browser) to[bend right=50] node[midway,above] {(4) signed contract} node[midway,below] {(signal)} (wallet); \draw[to] (wallet) to[bend right=50] node[midway,above] {(signal)} node[midway,below] {(5) signed coins} (browser); \draw[<->] (browser) -- node[midway,above] {(3,6) custom} node[midway,below] {(HTTP(S))} (shop); \draw[to] (shop) to[bend right=50] node[midway,above] {(HTTP(S))} node[midway,below] {(1) proposed contract / (7) signed coins} (backend); \draw[to] (backend) to[bend right=50] node[midway,above] {(2) signed contract / (8) confirmation} node[midway,below] {(HTTP(S))} (shop); \end{tikzpicture} \end{center} \caption{Both the customer's client and the merchant's server execute sensitive cryptographic operations in a secured background/backend that is protected against direct access. Interactions with the Taler exchange from the wallet background to withdraw coins and the Taler backend to deposit coins are not shown. Existing system security mechanisms are used to isolate the cryptographic components (boxes) from the complex rendering logic (circles), hence the communication is restricted to JavaScript signals or HTTP(S), respectively.} \label{fig:frobearch} \end{figure*} Figure~\ref{fig:frobearch} shows how the secure payment components interact with the existing Web shop logic. First, the Web shop frontend is responsible for constructing the shopping cart. For this, the shop frontend generates the usual Web pages, which are transmitted to the customer's browser. Once the order has been constructed, the shop frontend provides a {\em proposed contract} in JSON format to the payment backend, which signs it and returns it to the frontend. The frontend then transfers the signed contract over the network, and passes it to the wallet (sample code for this is shown in Figure~\ref{listing:contract}). Here, the wallet operates from a secure {\em background} context on the client side. From this background context the wallet allows the user to securely accept the payment. By running in the background context, the wallet can performs the cryptographic operations protected from the Web shop. In particular, the architecture is secure against a merchant that generates a page that looks like the wallet's payment page (Figure~\ref{subfig:payment}), as such a page would still not have access to the private keys of the coins that are exclusive to the background context. If the user accepts, the resulting signed coins are transferred from the client to the server again using a protocol that the merchant can customize to fit the existing infrastructure. Instead of adding any cryptographic logic to the merchant frontend, the generic Taler merchant backend allows the implementor to delegate coin handling to the payment backend, which validates the coins, deposits them at the exchange, and finally validates and persists the receipt from the exchange. The merchant backend then communicates the result of the transaction to the front\-end, which is then responsible for executing the business logic to fulfill the order. As a result of this setup (Figure~\ref{fig:frobearch}), the cryptographic details of the Taler protocol do not have to be re-implemented by each merchant. Instead, existing Web shops implemented in a multitude of programming languages can straightforwardly add support for Taler by: {\bf (0)} detecting in the browser that Taler is available; {\bf (1)} upon request, generating a contract in JSON based on the shopping cart; {\bf (2)} allowing the backend to sign the contract before sending it to the client; {\bf (7)} passing coins received in payment for a contract to the backend; and, {\bf (8)} executing fulfillment business logic if the backend confirms the validity of the payment. To setup a Taler backend, the merchant only needs to let it know his wire transfer routing details, such as his IBAN number. Ideally, the merchant might also want to obtain a certificate for the public key generated by the backend for improved authentication. Otherwise, the customer's authentication of the Web shop simply continues to rely upon HTTPS/X.509. \section{Discussion} We will now discuss how customer's may experience relevant operational risks and failure modes of Taler, and relate them to failure modes in existing systems. % \smallskip \subsection{Security risks} In Taler, customers incur the risk of wallet loss or theft. We believe customers can manage this risk effectively because they manage similar risks of losing cash in a physical wallet. Unlike physical wallets, Taler's wallet could be backed up to secure against loss of a device. Taler's contracts do provide a degree of protection for customers because they are signed by the merchant and retained by the wallet: while they mirror the paper receipts that customers may receive in physical stores, Taler's cryptographically signed contracts ought to carry more weight in courts than typical paper receipts. Point-of-sale systems providing printed receipts have been compromised in the past by merchants to embezzle sales taxes.~\cite{munichicecream} With Taler, the merchant still generates a receipt for the customer; however, the record for the tax authorities ultimately is anchored with the exchange's wire transfer to the merchant. Using the subject of the wire transfer, the state can trace the payments and request the merchant to provide cryptographically matching contracts. Thus, this type of tax fraud is no longer possible, which is why we call Taler {\em taxable}. The mere threat of the state sometimes tracing transactions and contracts back to the merchant also makes Taler unsuitable for illegal activities. The exchange operator is obviously crucial for risk management in Taler, as the exchange operator holds the customer's funds in a reserve in escrow until the respective deposit request arrives\footnote{As previously said, this {\it deposit request} is aimed to translate {\it coins} into real money and it's accomplished by a merchant after successfully receiving coins by a wallet. In other words, it is the way merchants get real money on their bank accounts}. To ensure that the exchange operator does not embezzle these funds, Taler expects exchange operators to be regularly audited by an independent auditor\footnote{Auditors are typically run by financial regulatory bodies of states}. The auditor can then verify that the incoming and outgoing transactions and the current balance of the exchange match the logs with the cryptographically secured transaction records. % \smallskip \subsection{Failure modes} There are several failure modes the user of a Taler wallet may encounter: \begin{itemize} \item As Taler supports multiple exchanges, there is a chance that a merchant might not support any exchange where the customer withdrew coins from. We mitigate this problem by allowing merchants to support all exchanges audited by a particular auditor. We believe this a reasonable approach, because auditors and merchants must operate with a particular legal and financial framework anyways. We note that a similar failure mode exists with credit cards, where not all merchants accept all issuers, especially internationally. \item Restoring the Taler wallet state from previous backups, or copying the wallet state to a new machine, may cause honest users to attempt to double spend coins, as the wallet does not know when coins are spent between backup and recovery. In this case, the exchange provides cryptographic proof that the coins were previously spent, so the wallet can verify that the exchange and merchant are behaving honestly. % FIXME FIXME: the following paragraph seems to describe a scenario where the % wallet lost coins due to a restore from backup and then ask for refresh % of lost coins: but how does the wallet know lost coins' public keys? % CG: I don't understand the problem. % % Also in this paragraph: how can a payment end in-flight due to insufficient % funds? If the payment has been started by the wallet, then no 'insufficient % funds' may occur, otherwise the wallet would not have started the payment. % % CG: Yes, as I explain if the Wallet isn't aware that some coins were % already spent (I make a backup, spend coins, restore backup, try to % spend again), then this may happen. % % A way to fix that could be to better define 'internal invariants' .. % % CG: The internal invariant is exactly the one you fell upon: % That the wallet knows which coins have been spent! \item There could be insufficient funds in the Taler wallet when making a payment. Usually the wallet can trivially check this before beginning a transaction, but when double-spending is detected this may also happen after the wallet already initiated the payment. This would usually only happen if the wallet is unaware of a backup operation voiding its internal invariants. If a payment fails in-flight due to insufficient funds, the wallet can use Taler's refresh protocol to obtain a refund for those coins that were not actually double-spent, and then explain the user that the balance was inaccurate due to inconsistencies from recovery, and overall insufficient for payment. For the user, this failure mode appears equivalent to an insufficient balance or credit line when paying with cards. \end{itemize} \subsection{Comparison} The different payment systems discussed make use of different security technologies, which has an impact on their usability and the assurances they can provide. Except for Bitcoin, all payment systems described involve an authentication step. % FIXME alternative for the following sentence: % With Taler, the authentication is implicit when withdrawing, since % the user has to login into his bank's Web portal in the first place, % and no further authentication is required during the whole payment % experience. % CG: Not exactly, as the authentication to the bank is still % a very explicit authentication step. It's just more natural. With Taler, the authentication itself is straightforward, as the customer is at the time visiting the Web portal of the bank, and the authentication is with the bank (Figure~\ref{fig:taler-withdraw}). With PayPal, the shop redirects the customer to the PayPal portal (step 5 in Figure~\ref{fig:paypal}) after the user selected PayPal as the payment method. The customer then provides the proof of payment to the merchant. Again, this is reasonably natural. The 3DS workflow (Figure~\ref{fig:cc3ds}) has to deal with a multitude of banks and their different implementations, and not just a single provider. Hence, the interactions are more complicated as the merchant needs to additionally perform a lookup in the card scheme directory and verify availability of the bank (steps 8 to 12). The key difference between Taler and 3DS or PayPal is that in Taler, authentication is done ahead of time. After authenticating once to withdraw digital coins, the customer can perform many micropayments without having to re-authenticate. While this simplifies the process of the individual purchase, it shifts the mental overhead to an earlier time, and thus requires some planning, especially given that the digital wallet is likely to only contain a % FIXME line below: which 'funds'? Coins or real money? (If they are % coins, recall that the wallet withdraw all the coins from a fresh % reserve, so there is no 'fraction' of user's available funds; at % least in the current implementation) % I originally wrote ``wealth'' or ``net value'', but given that % most customers are in debt today, that makes little sense, so % I changed it to ``available funds'', but I meant _all_ the money % he has. small fraction of the customer's available funds. As a result, Taler improves usability if the customer is able to withdraw funds once to then facilitate many micropayments, while Taler is likely less usable if for each transaction the customer first visits the bank to withdraw funds. This is deliberate, as Taler can only achieve reasonable privacy for customers if they do keep a balance in their wallet, thereby breaking the association between withdrawal and deposit. % FIXME the sentence above can be in contrast with how the exchange % actually deposits funds to merchants, that is through 'aggregate % deposits' that may add unpredictable delays (but that doesn't affect % this article too much) % CG: I think mentioning aggregation here would distract. Bitcoin's payment process (Figure~\ref{fig:bitcoin}) resembles that of Taler in one interesting point, namely that the wallet is given details about the contract the user is to enter (steps 7 to 11). However, in contrast to Taler, here the Bitcoin wallet(s) are expected to fetch the ``invoice'' from the merchant, while in Taler the browser provides the Taler wallet with the proposed contract directly. In PayPal and 3DS, the user is left without a cryptographically secured receipt. Card-based payments (including 3DS) and PayPal also extensively rely on TLS for security. The customer is expected to verify that their connections to the various Web sites are properly authenticated using X.509, and to know that it is fine to provide their bank account credentials to the legitimate \url{verifiedbyvisa.com}.\footnote{The search query ``verifiedbyvisa.com legit'' is so common that, when we entered ``verifiedbyvisa'' into a search engine, it was the suggested auto-completion.} However, relying on users understanding their browser's indications of the security context is inherently problematic. Taler addresses this challenge by ensuring that digital coins are only accessible from fully wallet-generated pages, hence there is no risk of Web pages mimicking the look of the respective page, as they would still not obtain access to the digital coins. Once the payment process nears its completion, merchants need to have some assurance that the contract is now valid. In Taler, merchants obtain a non-repudiable confirmation of the payment. With 3DS and PayPal, the confirmation may be disputed later (i.e. in case of fraud), or accounts may be frozen arbitrarily~\cite{diaspora2011}. Payments in cash require the merchant to assume the risk of receiving counterfeit money. % FIXME what about (for the following sentence): merchants should care % about maintaining change and depositing the money earned % CG: No, it's not optional, ``should'' doesn't come into the equation % here. It's a mandatory business expense. Furthermore, merchants have the cost maintaining change and depositing the money earned. With Bitcoin, there is no definitive time until a payment can be said to be confirmed (step 19, Figure~\ref{fig:bitcoin}), leaving merchants in a bit of a tricky situation. \section{Conclusion} Customers and merchants should be able to easily adapt their existing mental models and technical infrastructure to Taler. In contrast, Bitcoin's payment models fail to match common expectations, be it in terms of performance, durability, security, or privacy. Minimizing the need to authenticate to pay fundamentally improves usability. % FIXME (following paragraph): it's never said that the Taler wallet % keeps any 'receipt' of transaction -- maybe here we want to say 'contract' % instead of 'receipt'? % CG: I'd say on the customer side, the signed contract is a receipt. % That should be intuitive. We expect that electronic wallets that automatically collect digitally signed receipts for transactions will become commonplace. A key question for the future is thus whether this data collection will be done on behalf of the citizens and under their control, or on behalf of the Reich of big data corporations. We encourage readers to try our prototype for Taler at \url{https://demo.taler.net/}, and to ponder why the billion dollar e-commerce industry still relies mostly on TLS for security, given that usability, security and privacy can clearly {\em all} be improved simultaneously using a modern payment protocol. % These APIs are all RESTful in the modern sense because that greatly % simplify integrating Taler with web shops and browsers. \section*{Acknowledgements} This work benefits from the financial support of the Brittany Region (ARED 9178) and a grant from the Renewable Freedom Foundation. \bibliographystyle{abbrv} \bibliography{ui,btc,taler,rfc} \appendix \begin{figure*} \begin{center} \includegraphics[width=0.95\textwidth]{figs/cc3ds.pdf} \end{center} \caption{Card payment processing with 3DS. (From: W3c Web Payments IG.)} \label{fig:cc3ds} \end{figure*} \begin{figure*} \includegraphics[width=\textwidth]{figs/bitcoin.pdf} \caption{Bitcoin payment processing. (From: W3c Web Payments IG.)} \label{fig:bitcoin} \end{figure*} \begin{figure*} \includegraphics[width=\textwidth]{figs/paypal.pdf} \caption{Payment processing with Paypal. (From: W3c Web Payments IG.)} \label{fig:paypal} \end{figure*} % \tinyskip \lstdefinelanguage{JavaScript}{ keywords={typeof, new, true, false, catch, function, return, null, catch, switch, var, if, in, while, do, else, case, break, for}, keywordstyle=\color{blue}\bfseries, ndkeywords={class, export, boolean, throw, implements, import, this}, ndkeywordstyle=\color{darkgray}\bfseries, identifierstyle=\color{black}, sensitive=false, comment=[l]{//}, morecomment=[s]{/*}{*/}, commentstyle=\color{purple}\ttfamily, stringstyle=\color{red}\ttfamily, morestring=[b]', morestring=[b]" } \begin{figure*} \lstset{language=JavaScript} \lstinputlisting{figs/taler-presence.js} \caption{Sample code to detect the Taler wallet. Allowing the Web site to detect the presence of the wallet leaks one bit of information about the user. The above logic also works if the wallet is installed while the page is open.} \label{listing:presence} \end{figure*} \begin{figure*} \lstset{language=JavaScript} \lstinputlisting{figs/taler-contract.js} \caption{Sample code to pass a contract to the Taler wallet. Here, the contract is fetched on-demand from the server. The {\tt taler\_pay()} function needs to be invoked when the user triggers the checkout.} \label{listing:contract} \end{figure*} \end{document} % \smallskip \subsection{Anonymity} We strongly recommend that the user use Tor Browser to protect their % FIXME wasn't the use of Tor discouraged to login into personal things? IP address, both initially when withdrawing coins and later during purchases. There are lingering risks that anonymous coins can be correlated to customers using additional information. After withdrawing coins, customer should usually wait before spending them, as spending them immediately .... % wallet determines coin denominations Wallet provides isolation Near copy from EXIST proposal? - Limits user risk - Nearly eliminates risk for merchant and exchange - lower transaction fees - Reserves simplify things Denomination choice - Anonymity refresh protocol - Withdraw automates like ATMs Browser extension - RESTful vs Bitcoin, OpenCoin, etc. - Retrying RESTful transactions always works - minimizing dialog - see & pay ?? - TBB integration - Needed anyways - Other browser integration? - Is it wise? Ok if not worried about anonymity Taler is still better - Is tor2web worse? - W3C Autopay? pat payment recognition? - dangerous? - high charges - good for funny money NFC % \smallskip \subsection{Risks} A Taler exchange's need not face significant financial risks beyond the risk of losing a denomination signing key. Exchanges can limit that risk by carefully tracking how much they issue in each denomination. Taler merchant's risks are limited primarily by depositing coins quickly and stating contracts accurately.