[NO TESTS] WIP
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7 changed files with 479 additions and 103 deletions
66
projects/garage/worktop.scad
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66
projects/garage/worktop.scad
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use <casters.scad>
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module beam($fn=$fn) {
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union() {
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translate([2, 0, 0])
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cube([24, 2, 4]);
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translate([26, 0, 2])
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rotate([-90, 0, 0])
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cylinder(r=2, h=2, $fn=$fn);
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}
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}
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module top() {
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translate([0, 0, 4])
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cube([24, 96, 0.75]);
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translate([0, 2, 0])
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beam();
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translate([0, 48, 0])
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beam();
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translate([0, 94, 0])
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beam();
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}
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module worktop() {
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translate([0, 0, 40]) {
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translate([6, 0, 0])
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cube([14, 2, 4]);
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translate([6, 92, 0])
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cube([14, 2, 4]);
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top();
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// the wing
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translate([52, 96, 0])
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rotate([0, 0, 180])
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top();
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// supports
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translate([0, 0, -4]) {
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}
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}
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for(x=[2, 20])
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for(y=[0, 92])
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translate([x, y, 0])
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cube([4, 2, 44]);
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translate([6, 0, 0])
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cube([14, 2, 4]);
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translate([0, 2, 0])
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cube([24, 2, 4]);
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translate([6, 92, 0])
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cube([14, 2, 4]);
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translate([0, 94, 0])
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cube([24, 2, 4]);
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}
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worktop();
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150
projects/garage/worktop2.scad
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150
projects/garage/worktop2.scad
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@ -0,0 +1,150 @@
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// 2x4" nominal lumber is really 38mm x 89mm x Z
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// Drawing unit: MM 1:1
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use <casters.scad>
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function in2mm(x) = 25.4 * x;
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module txf(height) {
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cube([38, 89, height]);
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}
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module post(height) {
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txf(height);
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}
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module dpost(height) {
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post(height);
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translate([38, 0, 0])
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post(height);
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}
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module frame(width, depth, height) {
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translate([38, 38, 0]) {
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dpost(height);
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}
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translate([38, 38 + 89 + in2mm(30), 0]) {
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dpost(height);
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}
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translate([38, depth - 89 - 38, 0]) {
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dpost(height);
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}
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// bottom bar
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translate([0, 0, 89])
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rotate([-90, 0, 0])
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txf(depth);
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// top bar
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let(inset=in2mm(30) + 38 + 89) {
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translate([0, inset, height])
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rotate([-90, 0, 0])
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txf(depth - inset);
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}
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// support
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translate([0, 0, height - in2mm(20)])
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rotate([-90, 0, 0])
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txf(in2mm(30) + 38 * 2 + 89 * 2);
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}
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module shelf(width, depth, thickness) {
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// FIXME: Is there more shelf geometry? A bottom box in 1x2 or something?
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cube([width, depth, thickness]);
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}
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module bench(width, depth, height,
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top_thickness=in2mm(0.75),
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shelf_width=in2mm(30),
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shelf_depth=in2mm(20)) {
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ch = 38 * 2 + 2;
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ph = height - ch - top_thickness;
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// The frame, at relative to caster plane coordinates.
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translate([0, 0, ch]) {
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frame(width, depth, ph);
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translate([width, 0, 0])
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mirror([1, 0, 0])
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frame(width, depth, ph);
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// top
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translate([0, 38 + 89 + in2mm(30), ph]) {
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cube([width, depth - 38 - 89 - shelf_width, top_thickness]);
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}
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translate([0, 0, ph]) {
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cube([width, 38 + 89, top_thickness]);
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}
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// Wing top
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// bottom bars
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translate([38, 38, 89])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, depth, 89])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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// "top" bars
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translate([38, 38, ph - shelf_depth])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, 38, ph])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, 38, ph - shelf_depth])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, 38*2 + 89*2 + shelf_width, ph - in2mm(20)])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, 38*2 + 89*2 + shelf_width, ph])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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translate([38, depth, ph])
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rotate([-90, 0, -90])
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txf(width - 38 * 2);
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// Reference shelf
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translate([0, 38 + 89, ph - shelf_depth/2])
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shelf(width, shelf_width, top_thickness);
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}
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// The casters, at absolute coordinates
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for (dx=[0, width-(38*3)])
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for (dy=[38, 38 + 89 + in2mm(30), depth-38-89])
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translate([dx + 38, dy + 89/2, 0])
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caster(
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// wheel (r, h)
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38, 30,
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// axel (r, h)
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5, 1,
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// bearing (r, h)
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10, 1,
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$fn=16
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);
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}
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module worktop2() {
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// 1:1mm to 1:1in because I want to consume this model in the 1:1in garage sketch
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scale([1/25.4, 1/25.4, 1/25.4]) {
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bench(in2mm(32), in2mm(96), in2mm(40), in2mm(0.75));
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}
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}
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worktop2();
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zapp_binary(
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name = "updater",
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main = "src/python/arrdem/updater/__main__.py",
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shebang = "/usr/bin/env python3",
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imports = [
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"src/python",
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],
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212
projects/shoggoth/DOC.md
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212
projects/shoggoth/DOC.md
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# "Documentation"
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## Ichor ISA
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### TRUE
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```() -> (bool)```
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Push the constant TRUE onto the stack.
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### FALSE
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```() -> (bool)```
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Push the constant FALSE onto the stack.
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### IF <target>
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```(bool) -> ()```
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Branch to another point if the top item of the stack is TRUE. Otherwise fall through.
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Note that not, and, or, xor etc. can all be user or prelude defined functions given if.
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### GOTO <target>
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```() -> ()```
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Branch to another point within the same bytecode segment. The target MUST be within the same module range as the
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current function. Branching does NOT update the name or module of the current function.
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### DUP <n>
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```(A, B, ...) -> (A, B, A, B, ...)```
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Duplicate the top N items of the stack.
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### ROT <n>
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```(A, B, ..., Z) -> (Z, A, B, ...)```
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Rotate the top N elements of the stack by 1.
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FIXME: What if you want to rotate by more than 1?
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### DROP <n>
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```(...: n, ...) -> (...)```
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Drop the top N items of the stack.
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### SLOT <n>
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```(..., A) -> (A, ..., A)```
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Copy the Nth (counting up from 0 at the bottom of the stack) item to the top of the stack.
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Intended to allow users to emulate (immutable) frame locals for reused values.
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### IDENTIFIERC <val>
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```() -> (IDENTIFIER)```
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An inline constant which produces an identifier to the stack.
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Identifiers name functions, fields and types but are not strings.
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They are a VM-internal naming structure with reference to the module.
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#### Function identifiers
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Function identifiers are written `<typevars>;<name>;<arglist>;<retlist>`.
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For example the signature of `not` is `;not;bool;bool`.
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Note that this name scheme allows for `;or;bool,bool;bool` and `;or;bool,bool,bool;bool` to co-exist simultaneously, and for overloading of names with type variables.
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One could also have written `or` as `T;or;<funref T;bool>,T,T;T` if one were able to provide a truly generic test
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This design is a deliberate reaction to the JVM which does not permit such name-overloading and is intended to enable semi-naive compilation of complex generic operations without munging or erasure.
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#### Type identifiers
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Type identifiers are written `<typevars>;<name>;<variantlist>`
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For example the signature of `bool` is `;bool;<true>,<false>`
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As with functions, this allows for generic overloading of names.
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For example one could define `tuple` as `;tuple;<tuple>`, `A;tuple;<tuple A>`, `A,B;tuple;<tuple A,B>`, and soforth simultaneously.
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### FUNREF
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```(IDENTIFIER) -> (<FUNREF ... A; ... B>)```
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Note that `;` ends a list here the arguments list and should be read as `to`.
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Construct a reference to a static codepoint.
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### CALLF <nargs>
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```(<FUNREF ... A; ... B>, ... A) -> (... B)```
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Call [funref]
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Make a dynamic call to the function reference at the top of stack.
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The callee will see a stack containg only the provided `nargs`.
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A subsequent RETURN will return execution to the next point.
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Executing a `CALL` pushes the name and module path of the current function.
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### RETURN <nargs>
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```(...) -> ()```
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Return to the source of the last `CALL`. The returnee will see the top `nargs` values of the present stack
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appended to theirs. All other values on the stack will be discarded.
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Executing a `RETURN` pops (restores) the name and module path of the current function back to that of the caller.
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If the call stack is empty, `RETURN` will exit the interpreter.
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### CLOSUREF <nargs>
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```(FUNREF<A, ... B; ... C>, A) -> (CLOSURE<... B; ... C>)```
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Construct a closure over the function reference at the top of the stack. This may produce nullary closures.
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### CLOSUREC <nargs>
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```(CLOSURE<A, ... B; ... C>, A) -> (CLOSURE<... B; ... C>)```
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Further close over the closure at the top of the stack. This may produce nullary closures.
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### CALLC <nargs>
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```(CLOSURE<... A; .. B>, ... A) -> (... B)```
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Call [closure]
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Make a dynamic call to the closure at the top of stack.
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The callee will see a stack containg only the provided `nargs` and closed-overs.
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A subsequent RETURN will return execution to the next point.
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Executing a `CALL` pushes the name and module path of the current function.
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### TYPEREF
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```(IDENTIFIER) -> (TYPEREF)```
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Produces a TYPEREF to the type named by the provided IDENTIFIER.
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### FIELDREF
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```(IDENTIFIER, TYPEREF) -> (FIELDREF)```
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Produces a FIELDREF to the field named by the provided IDENTIFIER.
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The FIELDREF must be within and with reference to a sum type.
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### VARIANTREF
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```(IDENTIFIER, TYPEREF) -> (VARIANTREF)```
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Produce a VARIANTREF to an 'arm' of the given variant type.
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### STRUCT <nargs>
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```(STRUCTREF<S>, ...) -> (S)```
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Consume the top N items of the stack, producing a struct of the type `structref`.
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The name and module path of the current function MUST match the name and module path of `structref`.
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The arity of this opcode MUST match the arity of the struct.
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The signature of the struct MUST match the signature fo the top N of the stack.
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### FLOAD
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```(FIELDREF<f ⊢ T ∈ S>, S) -> (T)```
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Consume the struct reference at the top of the stack, producing the value of the referenced field.
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### FSTORE
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```(FIELDREF<f ⊢ T ∈ S>, S, T) -> (S)```
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Consume the struct reference at the top of the stack and a value, producing a new copy of the struct in which
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that field has been updated to the new value.
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### VARIANT <nargs>
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```(VARIANTREF<a ⊢ A ⊂ B>, ...) -> (B)```
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Construct an instance of an 'arm' of a variant.
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The type of the 'arm' is considered to be the type of the whole variant.
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The name and module path of the current function MUST match the name and module path of `VARIANTREF`.
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The arity of this opcode MUST match the arity of the arm.
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The signature of the arm MUST match the signature fo the top N of the stack.
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### VTEST
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```(VARIANTREF<a ⊢ A ⊂ B>, B) -> (bool)```
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Test whether B is a given arm of a variant A .
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|
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### VLOAD
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```(VARIANTREF<a ⊢ A ⊂ B>, B) -> (A)```
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Load the value of the variant arm.
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VLOAD errors (undefined) if B is not within the variant.
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VLOAD errors (undefined) if the value in B is not an A - use VTEST as needed.
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|
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### ARRAY <nargs>
|
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```(TYPEREF<Y>, ... ∈ Y) -> (ARRAY<Y>)```
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|
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Consume the top N items of the stack, producing an array of the type `typeref`.
|
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|
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### ALOAD
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```(ARRAY<T>, NAT) -> (T)```
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Consume a reference to an array and an index, producing the value at that index.
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|
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FIXME: Or a signal/fault.
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### ASTORE
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```(ARRAY<T>, NAT, T) -> (ARRAY<T>)```
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Consume a value T, storing it at an index in the given array.
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Produces the updated array as the top of stack.
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|
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### BREAK
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Abort the interpreter
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## Appendix
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|
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https://wiki.laptop.org/go/Forth_stack_operators
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https://www.forth.com/starting-forth/2-stack-manipulation-operators-arithmetic/
|
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https://docs.oracle.com/javase/specs/jvms/se18/html/jvms-6.html#jvms-6.5.swap
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|
@ -4,9 +4,49 @@
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>
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> ~ Charlie Stross, "A Colder War"
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Shoggoth is a language designed to provide highly durable, portable agents.
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> The greatest performance improvement of all is when a system goes from not-working to working.
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>
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> ~ John Ousterhout
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Shoggoth runs atop a custom platform named Ichor, which aims to trivialize providing these properties.
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Shoggoth is a language designed to provide highly durable, portable processes.
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Much like Eve, it's intended to be an experiment at enabling classes of programs and making some hard things easier.
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Shoggoth runs atop a custom platform named Ichor, which aims to trivialize providing these properties and help the implementer focus by eliminating context.
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## Ichor
|
||||
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The Ichor virtual machine is a toy.
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||||
The implementation presented here is merely as an experimental platform providing a "clean slate" target for compilation.
|
||||
Ichor should be somewhat familiar to students of JVM bytecode, Fourth or UXN but has different priorities.
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||||
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Ichor is perhaps best explained as a reaction to the JVM.
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To be clear, the JVM is an incredible success story.
|
||||
But it has some decisions baked in that can't be walked back, such as the existence of `Object.equals()` and the primacy of classes for structuring both data and code.
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Ichor exists because it's much easier to define "snapshotting" the state of a flat loop bytecode interpreter with a stack than a recursive interpreter.
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The objectives of building durable and portable processes/actors in Shoggoth requires the ability to take a snapshot of program state and persist it to a shared store for REMOTE or EVENTUAL resumption.
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Think call/cc except with suspend or await happening across a network and database and scheduler boundary.
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||||
|
||||
Like the JVM, Ichor is a high-level 'struct' or 'object' oriented VM.
|
||||
Unlike the JVM which provides generics by using type erasure founded on casts and a shared bottom type (`Object`), Ichor has no `null` or ⊥ type.
|
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Ichor has only user-defined closed variant types and structs without inheritance or methods.
|
||||
|
||||
Unlike the JVM, Ichor names "functions" and "types" including their generic parameters.
|
||||
This allows for pervasive name overloading on both argument and return signature without the need for renaming or munging.
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||||
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||||
Unlike the JVM, Ichor does not make mutability readily available.
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||||
There is no concept of a mutable local value, or of a mutable variant or struct.
|
||||
"Place oriented programming" can be achieved only through explicit use of a mutable reference type which cannot be defined by the user.
|
||||
This is a bet that a platform founded on pervasive forwarding of immutability can prove viable.
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||||
It may not pan out.
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||||
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||||
Unlike most VMs, Ichor makes no effort to make user-defined C extensions easy.
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||||
They're likely to remain difficult-to-impossible as they conflict directly with other design priorities.
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## Shoggoth
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The Shoggoth language is an ML in Lisp's clothing.
|
||||
While notationally a Lisp due entirely to the implementer's preference, Shoggoth has far more in common with an ML or other statically and generically typed language than with a unityped Lisp or interpreted language.
|
||||
|
||||
## License
|
||||
|
||||
|
|
|
@ -146,17 +146,10 @@ XOR3 = BOOTSTRAP.define_function(
|
|||
]
|
||||
)
|
||||
|
||||
TRUE = BOOTSTRAP.define_type(
|
||||
"true",
|
||||
ProductExpr([]),
|
||||
)
|
||||
|
||||
FALSE = BOOTSTRAP.define_type(
|
||||
"false",
|
||||
ProductExpr([]),
|
||||
)
|
||||
|
||||
BOOL = BOOTSTRAP.define_type(
|
||||
"bool",
|
||||
SumExpr([TRUE, FALSE])
|
||||
";bool",
|
||||
{
|
||||
";true;": [],
|
||||
";false;": [],
|
||||
},
|
||||
)
|
||||
|
|
|
@ -192,15 +192,6 @@ class Opcode:
|
|||
|
||||
"""
|
||||
|
||||
class FIELDREF(t.NamedTuple):
|
||||
"""(IDENTIFIER, TYPEREF) -> (FIELDREF)
|
||||
|
||||
|
||||
Produces a FIELDREF to the field named by the provided IDENTIFIER.
|
||||
The FIELDREF must be within and with reference to a sum type.
|
||||
|
||||
"""
|
||||
|
||||
class VARIANTREF(t.NamedTuple):
|
||||
"""(IDENTIFIER, TYPEREF) -> (VARIANTREF)
|
||||
|
||||
|
@ -208,37 +199,6 @@ class Opcode:
|
|||
|
||||
"""
|
||||
|
||||
class STRUCT(t.NamedTuple):
|
||||
"""(STRUCTREF<S>, ...) -> (S)
|
||||
|
||||
Consume the top N items of the stack, producing a struct of the type `structref`.
|
||||
|
||||
The name and module path of the current function MUST match the name and module path of `structref`.
|
||||
The arity of this opcode MUST match the arity of the struct.
|
||||
The signature of the struct MUST match the signature fo the top N of the stack.
|
||||
"""
|
||||
|
||||
nargs: int = 0
|
||||
|
||||
class FLOAD(t.NamedTuple):
|
||||
"""(FIELDREF<f ⊢ T ∈ S>, S) -> (T)
|
||||
|
||||
Consume the struct reference at the top of the stack, producing the value of the referenced field.
|
||||
|
||||
"""
|
||||
|
||||
fieldref: str
|
||||
|
||||
class FSTORE(t.NamedTuple):
|
||||
"""(FIELDREF<f ⊢ T ∈ S>, S, T) -> (S)
|
||||
|
||||
Consume the struct reference at the top of the stack and a value, producing a new copy of the struct in which
|
||||
that field has been updated to the new value.
|
||||
|
||||
"""
|
||||
|
||||
fieldref: str
|
||||
|
||||
class VARIANT(t.NamedTuple):
|
||||
"""(VARIANTREF<a ⊢ A ⊂ B>, ...) -> (B)
|
||||
|
||||
|
@ -268,50 +228,8 @@ class Opcode:
|
|||
|
||||
"""
|
||||
|
||||
####################################################################################################
|
||||
# Arrays
|
||||
####################################################################################################
|
||||
class ARRAY(t.NamedTuple):
|
||||
"""(*) -> (ARRAY<Y>)
|
||||
|
||||
Consume the top N items of the stack, producing an array of the type `typeref`.
|
||||
|
||||
"""
|
||||
|
||||
typeref: str
|
||||
nargs: int
|
||||
|
||||
class ALOAD(t.NamedTuple):
|
||||
"""(ARRAY<T>, NAT) -> (T)
|
||||
|
||||
Consume a reference to an array and an index, producing the value at that index.
|
||||
|
||||
FIXME: Or a signal/fault.
|
||||
|
||||
"""
|
||||
|
||||
class ASTORE(t.NamedTuple):
|
||||
"""(ARRAY<T>, NAT, T) -> (ARRAY<T>)
|
||||
|
||||
Consume a value T, storing it at an index in the given array.
|
||||
Produces the updated array as the top of stack.
|
||||
|
||||
"""
|
||||
|
||||
####################################################################################################
|
||||
# Naturals
|
||||
####################################################################################################
|
||||
|
||||
####################################################################################################
|
||||
# Integers
|
||||
####################################################################################################
|
||||
|
||||
####################################################################################################
|
||||
# Ratios
|
||||
####################################################################################################
|
||||
|
||||
|
||||
class BREAK(t.NamedTuple):
|
||||
"""Abort the interpreter."""
|
||||
pass
|
||||
|
||||
|
||||
|
@ -347,10 +265,6 @@ class Module(t.NamedTuple):
|
|||
return i
|
||||
|
||||
def define_function(self, name, opcodes):
|
||||
# FIXME: This is way way WAAAAAAY too minimal. Lots of other stuff goes on a "function."
|
||||
# For instance how to install handlers?
|
||||
# How to consume capabilities?
|
||||
|
||||
try:
|
||||
sig = FunctionRef.parse(name)
|
||||
assert sig.name
|
||||
|
@ -364,8 +278,8 @@ class Module(t.NamedTuple):
|
|||
return name
|
||||
|
||||
def define_type(self, name, signature):
|
||||
# FIXME: What in TARNATION is this going to do
|
||||
pass
|
||||
self.types[name] = signature
|
||||
return name
|
||||
|
||||
def __str__(self):
|
||||
b = []
|
||||
|
|
Loading…
Reference in a new issue