a97ca91c1f
This is a big combined change. Other changes in this commit:
* Analyze makeinterface and make sure type switches don't include
unnecessary cases.
* Do not include CGo wrapper functions in the analyzer callgraph.
This also avoids some unnecessary type IDs.
* Give all Go named structs a name in LLVM.
* Use such a named struct for compiler-generated task data.
* Use the type and function names defined by the ssa and types
package instead of generating our own.
* Some improvements to function pointers.
* A few other minor improvements.
The one thing lacking here is interface-to-interface assertions.
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| lib | ||
| src | ||
| .gitignore | ||
| .gitmodules | ||
| analysis.go | ||
| arm.ld | ||
| avr.ld | ||
| avr.S | ||
| gen-device.py | ||
| Makefile | ||
| README.markdown | ||
| tgo.go | ||
TinyGo - Go compiler for microcontrollers
We never expected Go to be an embedded language and so it's got serious problems [...].
-- Rob Pike, GopherCon 2014 Opening Keynote
TinyGo is a project to bring Go to microcontrollers and small systems with a single processor core. It is similar to emgo but a major difference is that I want to keep the Go memory model (which implies garbage collection of some sort). Another difference is that TinyGo uses LLVM internally instead of emitting C, which hopefully leads to smaller and more efficient code and certainly leads to more flexibility.
My original reasoning was: if Python can run on microcontrollers, then certainly Go should be able to and run on even lower level micros.
Example program (blinky):
import "machine"
func main() {
led := machine.GPIO{machine.LED}
led.Configure(machine.GPIOConfig{Mode: machine.GPIO_OUTPUT})
for {
led.Low()
runtime.Sleep(runtime.Millisecond * 1000)
led.High()
runtime.Sleep(runtime.Millisecond * 1000)
}
}
Currently supported features:
- control flow
- many (but not all) basic types: most ints, strings, structs
- function calling
- interfaces for basic types (with type switches and asserts)
- goroutines (very initial support)
- function pointers (non-blocking)
Not yet supported:
- float, complex, etc.
- maps
- slices
- interface methods
- garbage collection
- defer
- closures
- channels
- introspection (if it ever gets implemented)
- standard library (needs more language support)
- ...
Analysis
The goal is to reduce code size (and increase performance) by performing all kinds of whole-program analysis passes. The official Go compiler doesn't do a whole lot of analysis (except for escape analysis) becauses it needs to be fast, but embedded programs are necessarily smaller so it becomes practical. And I think especially program size can be reduced by a large margin when actually trying to optimize for it.
Implemented analysis passes:
- Check which functions are blocking. Blocking functions a functions that call sleep, chan send, etc. It's parents are also blocking.
- Check whether the scheduler is needed. It is only needed when there are
gostatements for blocking functions. - Check whether a given type switch or type assert is possible with type-based alias analysis. I would like to use flow-based alias analysis in the future.