I may be late to the party in 2016. Play 2 is out, and the JDK (not to mention the hardware) drastically improved. I am not using Play or Spring Boot, since my platform doesn't need them - just pure runtime text/HTML generation from templates.
Whichever you chose, both SimpleTemplateEngine and MarkupTemplateEngine statically compile their templates, even though the Groovy doc only mentions it for the latter. Why wouldn't it generates a class for the former? I didn't compare them against each other, but I'd expect SimpleTemplateEngine to be faster, since it is... well, simpler - doesn't translate any syntax into String concatenations with ifs and loops in between.
And it is indeed very fast. I was concerned about invoking it in a loop. Doesn't make any difference. There is no overhead, as the template is compiled once.
I use multiple small templates responsible for generating individual form control markup (HTML + JS) to generate a composite form, included in a higher-level container, included in another container, and so on, until the entire page is formed. Decomposing your view like that makes it, as you already guessed, modular, encapsulated, and "object-oriented" - composed of many individual MVC components building upon each other. Sort of like good old custom JSP tags, only evaluated at runtime and compatible with technologies like Spring Boot, if you cannot resist trendy resume-boosting stuff like that.
A test form with a 100 fields (all complex "smart" controls with encapsulated state management and behavior) renders in 150ms the first time, and then 10-14ms thereafter. In an IDE debugger on my memory-starved 4y.o. notebook. I also verified it is thread-safe, since Groovy never mentioned it explicitly. Why wouldn't it be, if it is compiled into a stateless Groovy class like any other? Call createTemplate() once, store the Template somewhere, and use it (call Template.make()) in your servlet or another concurrent context. Obviously I'll never have a 100-field form in a real application. Anyone who does, needs to reconsider his/her UX.
The performance is quite adequate. I'd even accept one second to render a 100-field page. Think of it, you don't need ultimate nanotrading or nuclear missile tracking performance in a Web app. If you do, pick Jamon: http://www.jamon.org/Overview.html, which generates a Java class, you'd normally write to concatenate Strings. I didn't test it, as I don't like extra compilation steps (automatically executed by Maven, but still). Compiled Groovy bytecode is good enough for me - compared to the compiled, yes, strongly-typed Java. The difference would be marginal unless you are doing something complex, which you shouldn't inside a template (see below). Playing with typed Groovy variables vs. def as suggested in this thread, only saved me a couple of milliseconds on that 100-template run.
Templates should not have much procedural logic (internal variables, ifs and loops) anyway - that's the controller's, not view's responsibility. That said, ifs and loops are a must for a template engine. Why would one use Handlebars/Mustache, if he/she can simply call String.replace()?
The rest of the template engines is also irrelevant. No String concatenation (e.g. Velocity, or Freemarker) or interpreted JS-based technology (e.g. Jade) would ever beat the most direct Jamon's approach performance-wise. And being a Java programmer, you want to use your favorite language/syntax: either directly (Jamon) or 90% close to Java, Groovy is (being a scripting-centric concise interpreted Java). I wouldn't comment on Scala - the matter of preference. Other than its allegedly "concise" syntax (less and less relevant with Java 8+) comes at a price. And only matters for complex loops. You do not want to write your entire app inside one template, like I already said. A couple of loops and up to ten if statements max.
And, like everyone mentioned, the intuitive syntax, and ease of use is the key. They drastically reduce the number of bugs. A good (additional) server costs a $1000, while developer salaries - to fix all of the bugs stemming form the complexity of marginal performance optimization, are 100 times higher.