# TAL Assembler See also [the UXN virtual machine](./uxn.md) TAL is a Forth like two-pass assembler language translating directly to UXN memory images. ## Words Words are up to 63 consecutive non-whitespace characters. For instance `loop`, `System`, `Mouse/x`, `my-routine` and `some_other_routine` would all be examples of words. The UXN instructions themselves (`ADD`, `POP`, `LIT` and soforth) are all words. Some words have special interpretations. ### Opcodes See [the UXN documentation](./uxn.md) for a full listing of opcodes, but `BRK`, `INC`, `POP`, `NIP`, `SWP` .... `SFT` as words all mean their respective opcodes. These opcodes may be followed with the flags `k`, `r` or `2` to set the `keep`, `return` and `short` flags. For instance `INC2` as a word would increment a two-bit quantity at the top of the stack. `INC2k` would keep the original value, resulting in `x x+1` as the stack values. ### Numbers Hexadecimal numbers written with either two or four digits. For instance `00` would be the single word `0x00`. `0000` is equivalent to the two words `00 00`. UXN is little-endian, the value `0xFF00` is represented as the sequential words `FF 00`. To disambiguate, numbers are usually prefixed with `#`. ### Strings Words may be captured as ASCII formatted strings. Such strings are written `"`. For instance `"foo` would cause the bytes `#66 #6f #6f #00` to be literally inserted into the memory image. As `"` notation cannot capture whitespace, the `#20` (space), `#0a` (newline) and `#09` (tab) character constants are common. ## Comments Comments in TAL are written `( ... )` and support nesting. Eg. `( () )` is a valid comment. `( ( )` is not. TAL does not have a way to "close all start comments" like Java and some other languages do. ## Brackets `[` and `]` are treated as whitespace, and may be used for visual grouping. While they have semantics in traditional Forth, they have no semantics in TAL. ## Assembler directives ### Padding `|` "pad-absolute" pads the resulting UXN rom to a given absolute address. For instance `|0x0000` would explicitly align the assembler's point to `0x0000`. `$` "pad-relative" pads the UXN rom by the specified number of words (bytes). For instance `$2` would move the assembler's point forwards two words. ### Labels `@` defines a top-level label. For instance `@foo` would make the word `foo` a valid symbol for use elsewhere. Defining a top-level word establishes a scope within which sub-labels may be defined. `&bar` following `@foo` would create the label `foo/bar`. This can be used to create semantic tables. Numbers and opcodes cannot be created as labels. #### Example - the system device ```tal |00 @System &vector $2 &wst $1 &rst $1 &eaddr $2 &ecode $1 &pad $1 &r $2 &g $2 &b $2 &debug $1 &halt $1 ``` `|00` aligns the assembler to `0x0000`. This line of code creates the following symbols: - `System` at `0x0000` - `Sytstem/vector` at `0x0000` - `System/wst` at `0x0002`, shifted from `System/vector` by the `$2` - `System/rst` at `0x0003` - `System/eaddr` at `0x0004` - `System/ecode` at `0x0005` - `System/pad` at `0x0006` - `System/r` at `0x0008` - `System/g` at `0x000a` - `System/b` at `0x000c` - `System/debug` at `0x000e` - `System/halt` at `0x000f` ### Label References Labels may be referenced in one of seven ways: - Literal byte zero-page - `.label` - Raw byte relative - `_label` - Literal byte relative - `,label` - Raw byte absolute - `-label` - Raw short absolute - `:label` or `=label` - Literal short absolute - `;label` Literal labels are inserted with a `LIT` or `LIT2` as appropriate. Raw labels are inserted directly into bytecode. Absolute labels are double quantities. Relative labels are single signed byte quantities with a ±127 range. The zero page (`#00XX`) is used for program globals and convenient scratch space. Literal byte relative references ala `,foo` are used for control flow. Using only a single byte, these references have a range of ±127 instructions. A typical opcode sequences would be `,loop JMP`, eg. emit a relative address value to the loop label and perform a computed relative jump. For bytecode compactness, UXN programs tend to use computed rather than absolute jumps. The difference between single and double word references is critical, because the `LDR` instruction is a computed relative load, whereas `LDA` is an absolute short address load. ### Includes TAL files can include other files by writing `~`. For instance the `uxnasm.tal` file writes `~projects/library/string.tal` to include implementations of string functions. As with other preprocessor and assembler languages, TAL does not support namespacing, renaming or selective importing. - All included code is assembled at the point where it is included. - TAL does not support multiple definition or idempotent includes, and will error on repeated or recursive inclusion. ## Macros Macros are sequences of instructions which may be repeated. Macros are defined by writing `%macro-name { ... }`. The canonical UXNASM does not allow macros to exceed 64 words in size. When macros are invoked by using the macro-name as a bare word, the contents of the macro will be inserted. Sub-macro references are supported and will be expanded with no recursion guards or limit.