More comments - Pointers and Delegate

2021-01-21 01:53:00 +00:00 · 2021-01-21 01:53:00 +00:00 · 01d293f2c6
commit 01d293f2c6
parent 18b5da209d
2 changed files with 94 additions and 4 deletions
--- a/src/Delegate.c
+++ b/src/Delegate.c
@ -7,6 +7,29 @@
 #include <Data.h>
 #include <errno.h>

+/********************************************************************************
+ * The Delegate is what allows the compiler backend to be abstracted.           *
+ *                                                                              *
+ * It delegates the operation of compiling, assembling and linking              *
+ *  to the proper subsystems.                                                   *
+ *                                                                              *
+ * As of right now (20/01/2021) it uses the GCC backend.                        *
+ *                                                                              *
+ * Compile parses files to their AST and generates mingw PECOFF32+ assembly,    *
+ * Assemble uses GCC-as to compile the assembly to an object file.              *
+ * Link links the object files into an executable.                              *
+ *                                                                              *
+ ********************************************************************************/
+
+/*
+ * Files inputted must have a suffix/extension (because we're on Windows right now)
+ * This is the way to change the suffix for when a file is converted to another.
+ * 
+ * @param String: The full, current file name
+ * @param Suffix: The new, desired extension.
+ * 
+ */
+
 char* Suffixate(char* String, char Suffix) {
    char* Pos, *NewStr;

@ -26,6 +49,14 @@ char* Suffixate(char* String, char Suffix) {
    return NewStr;
 }

+
+/*
+ * Starts most of the work to do with the Erythro compiler.
+ * It:
+ *  Opens the input and output files,
+ *  Parses the global symbols of the file, including function blocks.
+ *  Generates the assembly representation of the source code
+ */
 char* Compile(char* InputFile) {
    char* OutputName;
    OutputName = Suffixate(InputFile, 's');
--- a/src/Pointers.c
+++ b/src/Pointers.c
@ -7,6 +7,34 @@
 #include <Defs.h>
 #include <Data.h>

+/****************************************************************
+ * Types are enumerated by the DataTypes enum.                  *
+ * They are represented by unsigned integers, where the         *
+ *  most significant 28 bits differentiate the raw type         *
+ *   of the data being encoded.                                 *
+ * However, the least significant nibble - that is,             *
+ *  the lowest 4 bits, represent the count of indirection.      *
+ *                                                              *
+ * This means that a raw Integer data type, such as an i32,     *
+ *  has the DataType representation 32.                         *
+ * However, a pointer to an Integer has DataType value 32+1,    *
+ *  or 33.                                                      *
+ *                                                              *
+ * This means that the maximum valid pointer level is 16.       *
+ *  That's a:                                                   *
+ *  ****************int                                         *
+ * That ought to be enough for everyone, right?                 *
+ *                                                              *
+ ****************************************************************/
+
+/*
+ * Adds 1 to the input Type, to add a level of indirection.
+ * If the indirection is already at 16 levels, it aborts.
+ * 
+ * @param Type: The DataType to pointerise
+ * @return the new pointerised DataType value.
+ */
+
 int PointerTo(int Type) {
    if((Type & 0xf) == 0xf)
        DieDecimal("Unrecognized type in pointerisation", Type);
@ -14,14 +42,35 @@ int PointerTo(int Type) {
    return (Type + 1);
 }

+/*
+ * Returns the underlying type behind a pointer.
+ * If the type is not a pointer (the lowest 4 bits are 0), it halts compliation.
+ * 
+ * @param Type: The type to un-dereference
+ * @return the underlying Type
+ */
+
 int ValueAt(int Type) {
    printf("\t\tDereferencing a %s\n", TypeNames(Type));
-    //TODO: this is still bullshittery!
    if((Type & 0xf) == 0x0)
        DieDecimal("Unrecognized type in defererencing", Type);
    return (Type - 1);
 }

+/*
+ * Type declarations may be raw, they may be pointers.
+ * If they are pointers, we need to be able to check
+ *  how many levels of indirection.
+ * However, being a pointer is optional.
+ * 
+ * This can parase in just a lone type specifier, or 
+ *  any valid level of indirection therefore.
+ * 
+ * @param Composite: unused
+ * @return the parsed DataType, with any indirection.
+ * 
+ */
+
 int ParseOptionalPointer(struct SymbolTableEntry** Composite) {

    int Type;
@ -61,12 +110,24 @@ int ParseOptionalPointer(struct SymbolTableEntry** Composite) {
            break;
        
        Type = PointerTo(Type);
-        Tokenise();
+        // Tokenise(); TODO: is this skipping pointers?
    }

    return Type;
 }

+
+/*
+ * Array Accesses come in the form of x[y].
+ * 
+ * x must be a pointer type, and an array structure.
+ * y can be any binary expression.
+ * 
+ * It is a wrapper around *((imax*)x + y).
+ * 
+ * @return the AST Node that represents this statement.
+ */
+
 struct ASTNode* AccessArray() {
    struct ASTNode* LeftNode, *RightNode;
    struct SymbolTableEntry* Entry;
@ -76,9 +137,7 @@ struct ASTNode* AccessArray() {
        DieMessage("Accessing undeclared array", CurrentIdentifier);
    
    LeftNode = ConstructASTLeaf(OP_ADDRESS, Entry->Type, Entry, 0);
-    //printf("\t\tCurrent token: %s\r\n", TokenNames[CurrentToken.type]);
    Tokenise();
-    //printf("\t\tCurrent token: %s\r\n", TokenNames[CurrentToken.type]);

    RightNode = ParsePrecedenceASTNode(0);