Macro density

lef21/resources/lef21.schema.json

@@ -363,6 +363,55 @@
         }
       ]
     },
+    "LefDensityGeometries": {
+      "title": "Lef Density Geometry Store",
+      "description": "Most LEF spatial data (e.g. ports, blockages) is organized by layer. [LefDensityGeometries] stores the combination of a layer (name) and a suite of rectangle density data on that layer.\n\n[LefDensityGeometries] are the primary building block of [LefDensity].",
+      "type": "object",
+      "required": [
+        "layer_name"
+      ],
+      "properties": {
+        "geometries": {
+          "description": "Geometries",
+          "type": "array",
+          "items": {
+            "$ref": "#/definitions/LefDensityRectangle"
+          }
+        },
+        "layer_name": {
+          "description": "Layer Name",
+          "type": "string"
+        }
+      }
+    },
+    "LefDensityRectangle": {
+      "title": "Lef Density Rectangle",
+      "description": "Defined as a rectangle with a numeric density value.  One or more of these geometries are associated with a layer name in [LefDensityGeometries]",
+      "type": "object",
+      "required": [
+        "density_value",
+        "pt1",
+        "pt2"
+      ],
+      "properties": {
+        "density_value": {
+          "description": "Density Value",
+          "type": "string",
+          "pattern": "^-?[0-9]+(\\.[0-9]+)?$"
+        },
+        "pt1": {
+          "description": "Location",
+          "allOf": [
+            {
+              "$ref": "#/definitions/LefPoint"
+            }
+          ]
+        },
+        "pt2": {
+          "$ref": "#/definitions/LefPoint"
+        }
+      }
+    },
     "LefEndCapClassType": {
       "description": "Sub-Types for Macros of Class [LefMacroClass::EndCap]",
       "oneOf": [
@@ -600,16 +649,14 @@
           ]
         },
         "density": {
-          "description": "Density Objects (Unsupported)",
-          "writeOnly": true,
-          "anyOf": [
-            {
-              "$ref": "#/definitions/Unsupported"
-            },
-            {
-              "type": "null"
-            }
-          ]
+          "description": "Density Objects",
+          "type": [
+            "array",
+            "null"
+          ],
+          "items": {
+            "$ref": "#/definitions/LefDensityGeometries"
+          }
         },
         "eeq": {
           "description": "Electrically-Equivalent Cell",

lef21/src/data.rs

@@ -208,11 +208,12 @@ pub struct LefMacro {
     #[builder(default)]
     pub fixed_mask: bool,
 
+    /// Density Objects
+    #[serde(default, skip_serializing_if = "Option::is_none")]
+    #[builder(default, setter(strip_option))]
+    pub density: Option<Vec<LefDensityGeometries>>,
+
     // Unsupported
-    /// Density Objects (Unsupported)
-    #[serde(default, skip_serializing)]
-    #[builder(default)]
-    pub density: Option<Unsupported>,
     /// Properties (Unsupported)
     #[serde(default, skip_serializing)]
     #[builder(default)]
@@ -391,6 +392,37 @@ pub struct LefLayerGeometries {
     #[builder(default, setter(strip_option))]
     pub width: Option<LefDecimal>,
 }
+
+/// # Lef Density Geometry Store
+///
+/// Most LEF spatial data (e.g. ports, blockages) is organized by layer.
+/// [LefDensityGeometries] stores the combination of a layer (name)
+/// and a suite of rectangle density data on that layer.
+///
+/// [LefDensityGeometries] are the primary building block of [LefDensity].
+///
+#[derive(Clone, Default, Builder, Debug, Deserialize, Serialize, JsonSchema, PartialEq, Eq)]
+#[builder(pattern = "owned", setter(into))]
+pub struct LefDensityGeometries {
+    // Required
+    /// Layer Name
+    pub layer_name: String,
+    /// Geometries
+    #[serde(default, skip_serializing_if = "Vec::is_empty")]
+    pub geometries: Vec<LefDensityRectangle>,
+}
+
+/// # Lef Density Rectangle
+/// Defined as a rectangle with a numeric density value.  One or more of these geometries are associated
+/// with a layer name in [LefDensityGeometries]
+#[derive(Clone, Debug, Deserialize, Serialize, JsonSchema, PartialEq, Eq)]
+pub struct LefDensityRectangle {
+    /// Location
+    pub pt1: LefPoint,
+    pub pt2: LefPoint,
+    /// Density Value
+    pub density_value: LefDecimal,
+}
 /// # Lef Via Instance
 ///
 /// A located instance of via-type `via_name`, typically used as part of a [LefLayerGeometries] definition.
@@ -648,6 +680,13 @@ enumstr!(
         Mask: "MASK",
         UseMinSpacing: "USEMINSPACING",
 
+        Density: "DENSITY",
+        TaperRule: "TAPERRULE",
+        NetExpr: "NETEXPR",
+        SupplySensitivity: "SUPPLYSENSITIVITY",
+        GroundSensitivity: "GROUNDSENSITIVITY",
+        MustJoin: "MUSTJOIN",
+
         // UNITS Fields
         Units: "UNITS",
         Time: "TIME",
@@ -680,11 +719,6 @@ enumstr!(
         AntennaMaxCutCar: "ANTENNAMAXCUTCAR",
 
         // Unsupported
-        TaperRule: "TAPERRULE",
-        NetExpr: "NETEXPR",
-        SupplySensitivity: "SUPPLYSENSITIVITY",
-        GroundSensitivity: "GROUNDSENSITIVITY",
-        MustJoin: "MUSTJOIN",
         Property: "PROPERTY",
         ManufacturingGrid: "MANUFACTURINGGRID",
         ClearanceMeasure: "CLEARANCEMEASURE",

lef21/src/read.rs

@@ -305,6 +305,7 @@ pub enum LefParseContext {
     Geometry,
     Site,
     Units,
+    Density,
     Unknown,
 }
 #[derive(Debug, Clone, PartialEq, Eq, Serialize, Deserialize)]
@@ -623,6 +624,9 @@ impl<'src> LefParser<'src> {
                     self.expect(TokenType::SemiColon)?;
                     mac.source(e)
                 }
+                LefKey::Density => {
+                    mac.density(self.parse_density()?)
+                }
                 LefKey::End => {
                     self.advance()?; // End of Macro. Eat the END key
                     break;
@@ -790,6 +794,54 @@ impl<'src> LefParser<'src> {
         self.ctx.pop();
         Ok(LefPort { layers, class })
     }
+    /// Parse a MACRO::DENSITY definition into a [Vec<LefDensityGeometries>]
+    fn parse_density(&mut self) -> LefResult<Vec<LefDensityGeometries>> {
+        self.ctx.push(LefParseContext::Density);
+        self.expect_key(LefKey::Density)?;
+        let mut dens_geoms: Vec<LefDensityGeometries> = Vec::new();
+
+        // Parse attributes and geometries
+        // Note this peeks rather than taking the next token,
+        // largely to accommodate the closing-delimeter-free `LAYER` / [LefDensityGeometries] definitions.
+        // Other keys generally advance by a Token *after* matching.
+
+        loop {
+            match self.peek_key()? {
+                LefKey::Layer => {
+                    self.expect_key(LefKey::Layer)?; // Eat the opening LAYER keyword
+                    let mut layer = LefDensityGeometriesBuilder::default();
+                    layer = layer.layer_name(self.parse_ident()?); // Parse the layer-name
+                    self.expect(TokenType::SemiColon)?;
+                    let mut rects: Vec<LefDensityRectangle> = Vec::new();
+
+                    loop {
+                        match self.peek_key()? {
+                            LefKey::Layer | LefKey::End => break, // End of geometries. (Really start/end of something else.)
+                            LefKey::Rect => {
+                                self.advance()?; // Eat the RECT keyword
+                                let p1: LefPoint = self.parse_point()?;
+                                let p2: LefPoint = self.parse_point()?;
+                                let dens_value: LefDecimal = self.parse_number()?;
+                                rects.push(LefDensityRectangle { pt1: p1, pt2: p2, density_value: dens_value });
+                                self.expect(TokenType::SemiColon)?;
+                            }
+                            _ => self.fail(LefParseErrorType::InvalidKey)?,
+                        }
+                    }
+                    layer = layer.geometries(rects);
+                    let layer = layer.build()?;
+                    dens_geoms.push(layer);
+                }
+                LefKey::End => {
+                    self.advance()?; // Eat the END Token
+                    break;
+                }
+                _ => self.fail(LefParseErrorType::InvalidKey)?,
+            }
+        }
+        self.ctx.pop();
+        Ok(dens_geoms)
+    }
     /// Parse a [LefMacro]'s obstruction definitions
     fn parse_obstructions(&mut self) -> LefResult<Vec<LefLayerGeometries>> {
         self.expect_key(LefKey::Obs)?;
@@ -835,7 +887,7 @@ impl<'src> LefParser<'src> {
         // and exit when another LAYER or END (of a higher-level thing) turn up.
         // Note that on end-of-file, i.e. `peek_token` returning `None`, this will exit and return a valid [LefLayerGeometries].
         // (Objects above it in the tree may error instead.)
-        let mut geoms = Vec::new();
+        let mut geoms: Vec<LefGeometry> = Vec::new();
         let mut vias = Vec::new();
         loop {
             if self.peek_token().is_none() {
@@ -890,7 +942,7 @@ impl<'src> LefParser<'src> {
                 }
                 // Parse the two points
                 let p1 = self.parse_point()?;
-                let p2 = self.parse_point()?;
+                let p2: LefPoint = self.parse_point()?;
                 self.expect(TokenType::SemiColon)?;
                 // And return the Rect
                 Ok(LefGeometry::Shape(LefShape::Rect(mask, p1, p2)))

lef21/src/tests.rs

@@ -115,6 +115,28 @@ fn it_parses_lib2() -> LefResult<()> {
     Ok(())
 }
 
+#[test]
+fn it_parses_density_lib() -> LefResult<()> {
+    let src = r#"
+    VERSION 5.8 ;
+    UNITS DATABASE MICRONS 2000 ; END UNITS
+    MACRO macro_dens
+        CLASS BLOCK ;
+        SIZE 100.0 BY 100.0 ;
+        DENSITY
+        LAYER met6 ;
+        RECT 0.0 0.0 40.0 50.0 46.6 ;
+        RECT 0.0 50.0 100.0 100.0 90 ;
+        LAYER met2 ;
+        RECT 1.0 2.0 3.0 4.0 5.55 ;
+        END
+    END macro_dens
+    "#;
+    let lib = parse_str(src)?;
+    //check_yaml(&lib, &resource("lib2.yaml"));
+    Ok(())
+}
+
 #[test]
 fn it_parses_no_end_library_5p6() -> LefResult<()> {
     let src = r#"

lef21/src/write.rs

@@ -203,9 +203,10 @@ impl<'wr> LefWriter<'wr> {
             self.indent -= 1;
             self.write_line(format_args_f!("{End} "))?;
         }
-
-        // DENSTITY and PROPERTIES would go here
-        // if mac.density.is_some() { }
+        if let Some(ref v) = mac.density {
+            self.write_density(v)?;
+        }
+        // PROPERTIES would go here
         // if mac.properties.is_some() { }
 
         self.indent -= 1;
@@ -354,6 +355,23 @@ impl<'wr> LefWriter<'wr> {
         self.write_line(format_args_f!("{Symmetry} {symmstr} ;"))?;
         Ok(())
     }
+
+    /// Write the DENSITY construct which includes LAYER and density RECT statements.
+    fn write_density(&mut self, dens_geoms: &Vec<LefDensityGeometries>) -> LefResult<()> {
+        use LefKey::{Density, End, Layer, Rect};
+        self.write_line(format_args_f!("{Density} "))?;
+        self.indent += 1;
+        for layer_geom_set in dens_geoms.iter() {
+            self.write_line(format_args_f!("{Layer} {layer_geom_set.layer_name} ; "))?;
+            for dens_rect in layer_geom_set.geometries.iter() {
+                self.write_line(format_args_f!("{Rect} {dens_rect.pt1} {dens_rect.pt2} {dens_rect.density_value} ; "))?;
+            }
+        }
+        self.indent -= 1;
+        self.write_line(format_args_f!("{End} "))?;
+        Ok(())
+    }
+
     /// Write the [LefMacroClass] enumerations.
     /// Note most sub-types use their macro-generated [Display] implementations.
     fn write_macro_class(&mut self, class: &LefMacroClass) -> LefResult<()> {