Descartes SDK allows Cartesi DApps to specify and request verifiable computations to Cartesi Machines. Additionally, the SDK provides tools to facilitate and reduce the cost of inputing data into Cartesi Machines.
Cartesi offers developers all the power of Linux when implementing the logic of their DApps. This statement becomes clear as the developer understands the Cartesi Machine, which is the main component of the Descartes Node.
The Cartesi Machine is similar in spirit to a virtualization solution like VirtualBox, KVM or VMWare. Inside of it, there is an operating system, hard drives, programs and data. Moreover, Cartesi Machines come with the important feature of being fully reproducible, which is an essential ingredient for consensus and dispute resolutions.
For the purpose of this section, one can think of a Cartesi Machine as a black box. A Virtual Machine with a set of input drives and a single output drive. When switched on, the machine boots a Linux operating system and passes the control to the software coded by the developer. This program is able to read the content of the input drives using traditional file operations available in any major programming language, process them and write results to the output drive.
To make this description more concrete, here are but a few examples of computations that can be performed inside a Cartesi Machine:
Cartesi's technical specification contemplates an unbounded number of participating nodes verifying the computation, as specified by each DApp. In general terms, there are numerous possible ways in which nodes could be allocated and arranged, depending on the type of DApp and how their users interact with it. This is covered in detail in a specific article that discusses topologies of Descartes DApps.
The Descartes SDK itself is currently restricted to two participating nodes, but this limitation will be removed in its next release. These two nodes assume the roles of claimer and challenger. The claimer is the node in charge of posting the result of the computation to the blockchain. Although challengers are equally interested in the result, they do not post a claim to the blockchain. Instead, they run the same computation off-chain, verifying the result informed by the claimer. Challengers remain silent on-chain during the challenging period, unless they disagree with the claimer's result. In that case, they start a dispute resolution process.
DApp users are not required to know if their nodes are playing the role of a claimer or challenger. These roles are managed automatically by the Descartes Node logic, as explained in the next sections.