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<h1>6502bench SourceGen: Intro</h1>
<p><a href="index.html">Back to index</a></p>
<h2><a name="overview">Overview</a></h2>
<p>SourceGen converts 6502/65C02/65816 machine-language programs to
assembly-language source.</p>
<p>SourceGen has two purposes. The first is to be a really nice
disassembler for the 6502 and related CPUs. Code tracing with status
flag tracking makes it easier to separate the code from the data,
automatic formatting of ASCII strings and filled-data areas helps
get the data regions sorted out, and modern IDE-style features like
cross-reference generation and color-highlighted bookmarks help
navigate the code while trying to figure out what it does. A
disassembler should help you understand the code, not just dump the
instructions to a text file.</p>
<p>The computer I built in 2014 has a 4GHz CPU and 8GB of RAM.
I figured we should put that kind of power to good use.</p>
<p>The second purpose is to facilitate sharing and collaboration. Most
disassemblers generate output for a specific assembler, or in a way that's
generic enough to match most any assembler; either way, you're left with
a text file in somebody's idea of the "correct" format. SourceGen keeps
everything in an assembler-neutral format, and provides numerous options
for customizing the display, so that multiple people viewing the same
project can each do so with the conventions they are accustomed to.
Code and data operands can be formatted in various numeric formats or
as symbols.
The project file uses a text format that is fairly diff-friendly, so
sharing projects through git works reasonably well. If you want source
code you can assemble, SourceGen will generate code optimized for the
assembler of your choice.</p>
<p>The sharing and collaboration ideas only work if the formatting
capabilities within SourceGen are sufficiently flexible. If you need to
generate assembly source and tweak it a bunch to express the intent of
the original code, then passing a SourceGen project around won't work.
This sort of thing is a bit outside the bounds of what a typical
disassembler does, so it remains to be seen whether SourceGen succeeds at
what it's trying to do, and also whether what it's trying to do is
something that people actually want.</p>
<p>You can get started by watching the
<a href="https://youtu.be/dalISyBPQq8">demo video</a> and playing with the
<a href="tutorials.html">tutorials</a>.</p>
<h2><a name="fundamental-concepts">Fundamental Concepts</a></h2>
<p>The next few sections present some general concepts and terminology. The
rest of the documentation assumes you've read and understood this. It will
be helpful if you already understand something about the 6502 instruction
set and assembly-language programming, but disassembling other programs is
actually a pretty good way to learn how to code in assembly.</p>
<h2><a name="begin">About 6502 Code</a></h2>
<p>For brevity's sake, "6502 code" should be taken to mean "code for
the 6502 CPU or any of its derivatives, including but not limited to
the 65C02 and 65816". So let's talk about 6502 code.</p>
<p>Code usually arrives in a big binary blob. Some of it will be
instructions, some of it will be data, some will be empty space used
for variable storage. Part of the challenge of disassembly is
identifying which parts of the file contain which.</p>
<p>Much of the code you'll find for the 6502 was written by humans,
rather than generated by a compiler, which means it won't conform to a
standard set of conventions. However, most programmers will use
subroutines, which can be identified and analyzed in isolation. Subroutines
are often interspersed with variable storage, referred to as a "stash".
Variables may be single-byte or multi-byte, the latter typically
in little-endian byte order.</p>
<p>Much of the data in a typical program is read-only, often in the
form of graphics or ASCII string data. Graphics can be difficult
to recognize automatically, but strings can be identified with a
reasonable degree of confidence. Address tables, which are a collection
of addresses to other things, are also fairly common.</p>
<p>A simple disassembler would start at the top of the file and just
start converting bytes to instructions. Unfortunately there's no reliable
way to tell the difference between instructions, data, and variable
stashes. When the converter hits data bytes it'll start generating
instructions that won't make sense. You'll have another problem when the
data ends and code resumes: 6502 instructions are variable-length, so if
the last byte of the data area appears to be a three-byte instruction,
the first two bytes of the next instruction area will be gobbled up.</p>
<p>Some programmers will use a trick where they "embed" an instruction
inside another instruction. This allows code to branch to two different
entry points, one of which will set a flag or load a register, and then
continue on to common code.</p>
<p>Another trick is to embed "inline data" after a JSR or JSL instruction.
The caller pulls the calling address off the stack, uses it to access
the parameters, then pushes the address back on after modifying it to
point to an address past the inline data. This can be very confusing
for the disassembler, which will try to interpret the inline data as
instructions.</p>
<p>Sometimes code is loaded at one location, then moved to another and
executed there. If you're disassembling an executing program you don't
have to worry about this, but if you're disassembling the binary from the
loadable file on disk then you need to track the address changes. The
address is communicated to the assembler with a "pseudo-opcode", usually
something like "ORG". Other pseudo-op directives are used to define external
symbols and (for 65816 code) register widths.</p>
<p>The 8-bit CPUs have a 16-bit (64KiB) address space, so addresses can
range from $0000 to $ffff. (I'm going to write hex values with a
preceding '$', like "$12ab", rather than "0x12ab" or "12abh", because
that's what 6502 systems commonly used.) The 65816 has a 24-bit address
space, but it's not contiguous -- a branch that extends past the end will
wrap around to the start of the 64KiB "bank". For 16-bit instruction
operands, the bank is identified for instruction and data addresses
by the program bank register and the data bank register, respectively.
The disassembler can't generally know the contents of the data bank
register, which makes life a bit more interesting.</p>
<p>The 6502 has an 8-bit processor status register ("P") with a bunch of flags
in it. Some of the flags determine whether a conditional branch is taken
or not, which is important because some branches appear to be conditional
but actually are always or never taken in practice. The disassembler needs
to be able to figure this out so that it doesn't try to disassemble the
bytes that follow an always-taken branch.
A more significant concern is the M and X flags found on the 65802/65816,
which determine the width of the registers and of immediate load
instructions. If you don't know what state the flags are in, you can't
know whether <code>LDA #value</code> is two bytes or three, and the
disassembly of the instruction stream will come out wrong.</p>
<h2><a name="sgintro">How SourceGen Works</a></h2>
<p>SourceGen employs a partial emulation technique that traces the flow
of execution. Most of what a given instruction does isn't important;
only its effect on the flow of execution matters.
<p>The code tracing has to start somewhere, so SourceGen uses "code entry
point hints" to identify places where execution may begin. By default,
a hint is placed at the start of the file. From there, the tracing process
walks through the code, pursuing all branches. In many cases, if you
mark all external entry points, SourceGen will automatically find all
executable code and separate it from variable storage and data areas.</p>
<p>As noted earlier, tracking the processor status flags can make the
analysis more accurate. Identifying situations where a branch instruction
is always or never taken avoids mis-categorizing a data region as code.
On the 65816, it's absolutely crucial to track the M/X flags, since those
affect the width of instructions. SourceGen tracks the value of the
processor flags at every instruction, blending sets of flags together when
multiple paths of execution converge.</p>
<p>Once instructions and data have been separated, the instruction operands
can be examined. Branches, loads, and stores that reference an address
that falls inside the address space covered by the file can be replaced
with a symbol. Operands that refer to addresses outside the file, such
as ROM or operating system routines, can be replaced with a symbol defined
by an equate directive.</p>
(For more details on how this works, see the
<a href="analysis.html">analysis appendix</a>.)
<h3><a name="scripts">Extension Scripts</a></h3>
<p>Extension scripts are C# source files that are compiled and
executed by SourceGen. They can be added to a project from SourceGen's
runtime data directory, or can live in the directory next to the project
file.</p>
<p>In the current implementation, scripts are only called to examine
JSR/JSL instructions. They can format nearby bytes as inline data, or
apply symbols to operands.</p>
<p>To reduce the chances of a script causing problems, all scripts are
executed in a sandbox with severely restricted access. Notably, nothing
in the sandbox can access files, except to read files from the PluginDll
directory.</p>
<p>The PluginDll directory lives next to the SourceGen executable, and
contains all of the compiled script DLLs, as well as two pre-built
application DLLs that plugins are allowed access to. The contents
are persistent, to avoid recompiling the scripts every time SourceGen
is launched, but may be manually deleted without harm.</p>
<h3><a name="hints">Analyzer Hints</a></h3>
<p>Sometimes SourceGen can't automatically find the start or end of an
instruction stream, or gets confused by inline data. These situations
can be resolved by adding an appropriate hint.</p>
<p><b>Code entry point hints</b> tell the analyzer to add the offset
to the list of instruction start points. Suppose you've got a code
library that begins with jump vectors, like this:</p>
<pre>
1000: 4c0910 JMP $1009
1003: 4cef10 JMP $10ef
1006: 4c3012 JMP $1230
1009: 18 CLC
</pre>
<p>When opened with SourceGen, it will look like this:</p>
<pre>
.ORG $1000
JMP L1009
.DD1 $4c
.DD1 $ef
.DD1 $10
.DD1 $4c
.DD1 $30
.DD1 $12
L1009 CLC
</pre>
<p>SourceGen doesn't see any code that jumps to $1003 or $1006, so it
assumes those are data. Further, the functions at those addresses may
also be considered data unless some bit of code reachable from L1009
calls into them. If you add a code hint to $1003 and $1006,
you'll get better results:
<pre>
.ORG $1000
JMP L1009
JMP L10ef
JMP L1230
L1009 CLC
</pre>
<p>Be careful that you only add hints to the instruction opcode. If
you selected the full range of bytes from $1003 to $1008, you would
end up with this:</p>
<pre>
.ORG $1000
JMP L1009
JMP &#9193; L10ef
BPL &#9193; L1053
JMP &#9193; L1230
BMI L101b
L1009 CLC
</pre>
<p>The exact set of instructions shown depends on your CPU configuration.
The problem is that the bytes in the middle of the instruction have
been marked as entry points, and SourceGen is treating them as
embedded instructions. $EF and $12 aren't valid 6502 opcodes, so
they're being ignored, but $10 is BPL and $30 is BMI.</p>
<p><b>Data hints</b> tell the analyzer when it should stop. For example,
suppose address $ff00 is known to always be nonzero, and the code uses
that fact to get a branch-always on the 6502:</p>
<pre>
.ORG $1000
LDA $ff00
BNE L1010
BRK $11
</pre>
<p>By placing a data hint on the BRK, you're telling the analyzer that
it should stop the current path of execution. (Note that this example
would actually be better solved by setting a status flag override on
the BNE that sets Z=0, so the code tracer will know it's a branch-always
and do the right thing.) It's only necessary to place a hint on the
very first (opcode) byte. Placing a data hint in the middle of what
SourceGen believes to be instruction will have no effect.</p>
<p><b>Inline data hints</b> identify bytes as being part of the
instruction stream, but not instructions. A simple example of this
is the ProDOS 8 call interface on the Apple II, which looks like this:</p>
<pre>
JSR $bf00
.DD1 $function
.DD2 $address
BCS BAD
</pre>
<p>The three bytes following the <code>JSR $bf00</code> should be hinted
as inline data, so that the code analyzer skips them and continues the
analysis at the <code>BCS</code>.</p>
<p>If code branches into a region that is marked as inline data, the
branch will be ignored.</p>
<h2><a name="sgconcepts">SourceGen Concepts</a></h2>
<p>As you work on a disassembled file, formatting operands and adding
comments, everything you do is saved in the project file as "meta data".
None of the data from the file being disassembled is included. This
should allow project files to be shared without violating the copyright
of the work being disassembled. (This will vary by region. Also, note
that the mere act of disassembling a piece of software may be illegal in
some cases.)</p>
<p>To avoid mix-ups where the wrong data file is used, the file's length
and CRC are stored in the project file. SourceGen will refuse to open a
project if the data file's length and CRC don't match.</p>
<p>Most of the data in the project file is associated with a file offset.
When you create a comment, you aren't associating it with line 53, you're
associating it with the 127th byte in the file. This ensures that, as the
project evolves, the comment you wrote is always connected to the
same instruction or data item. This also means you can't have two
comments on the same line -- each offset only has room for one. By
convention, file offsets are always shown as a six-digit hexadecimal value
with a leading '+', e.g. "+0012ab". This makes it easy to distinguish
between an address and a offset.</p>
<p>Instruction and data operands can be formatted in various ways. The
formatting choice is associated with the first offset of the item. For
instructions the number of bytes in the operand is determined by the opcode
(and, on the 65816, the M/X status flags). For data items the length
can be a single byte or an entire file. Operand formats are not allowed
to overlap.</p>
<p>When an instruction or data operand references an address, we call
it a <b>numeric reference</b>. When the target address has a label, and
the operand uses that symbol, we call that a <b>symbolic reference</b>.
SourceGen tries to establish symbolic references whenever possible,
so that the generated assembly source doesn't refer to hard-coded
locations within the program. Labels are generated automatically for
the targets of numeric references.</p>
<p>As your understanding of the disassembled code develops, you will want
to add comments explaining it. SourceGen projects have three kinds of
comments:</p>
<ol>
<li>End-of-line comments. As the name implies, these appear at the
end of a line, to the right of the opcode or operand.
<li>Long comments, also known as multi-line comments. These get a
line all to themselves, and may span multiple lines.
<li>Notes. Like long comments, these get a line to themselves. Unlike
long comments, these do not appear in generated assembly code. They
are a way for you to leave notes to yourself, perhaps "don't forget
to figure this out" or "this is the cool part".
</ol>
<p>Every file offset can have one of each.</p>
<p>Labels and comments may disappear if you associate them with a file
offset that is in the middle of a multi-byte instruction or data item.
For example, suppose you put a long comment at offset +000010, and then
mark a 50-byte region starting at offset +000008 as an ASCII string. The
comment won't be deleted, but won't be displayed either. The same thing
can happen to labels. SourceGen will try to prevent this from happening
by splitting formatted data into sub-regions at label boundaries.</p>
<h2><a name="about-symbols">All About Symbols</a></h2>
<p>A symbol has two parts, a label and a value. The label is a short
ASCII string; the value may be an 8-to-24-bit address or a numeric
constant. Symbols can be defined in different ways, and applied in
different ways.</p>
<p>The label syntax is restricted to a format that should be compatible
with most assemblers:</p>
<ul>
<li>2-32 characters long.
<li>Starts with a letter or underscore.
<li>Comprised of ASCII letters, numbers, and the underscore.
</ul>
<p>Label comparisons are case-sensitive, as is customary for programming
languages.</p>
<p><b>Platform symbols</b> are defined in platform symbol files. These
are named with a ".sym65" extension, and have a fairly straightforward
name/value syntax. Several files for popular platforms come with SourceGen
and live in the <code>RuntimeData</code> directory. You can also create your
own, but they have to live in the same directory as the project file.</p>
<p>Platform symbols can be addresses or constants. If an instruction
or data operand references an address outside the scope of the data
file, SourceGen looks for a symbol with a matching address value. If
it finds one, it automatically uses that symbol. Symbolic constants
can be used the same way, but are not matched automatically. This makes
them useful for things like operating system function numbers.</p>
<p>If two platform symbols have the same value, the one whose label comes
first alphabetically is used. If two platform symbols have the same label,
the most recently read one is kept.</p>
<p><b>Project symbols</b> behave like platform symbols, but they are
defined in the project file itself. The editor will prevent you from
creating two symbols with the same name. If two symbols have the same
value, the one whose label comes first alphabetically is used.</p>
<p>Project symbols always have precedence over platform symbols, allowing
you to redefine symbols within a project. (You can "hide" a platform
symbol by creating a project symbol with the same name and an unused
value, such as $ffffffff.)</p>
<p><b>User labels</b> are labels added to instructions or data by the user.
The editor won't allow you to add a label that conflicts, but if you
manage to do so, the user label takes precedence over project and platform
symbols. User labels may be tagged as local, global, or global and
exported. Local vs. global is important for the label localizer, while
exported symbols can be pulled directly into other projects.</p>
<p><b>Auto labels</b> are automatically generated labels placed on
instructions or data offsets that are the target of operands. They're
formed by appending the hexadecimal address to the letter "L", with
additional characters added if some other symbol has already defined
that label. Auto labels are only added where they are needed. Because
auto labels may be redefined or disappear, the editor will try to prevent
you from referring to them when editing operands.</p>
<p>Operands may use parts of symbols. For example, if you have a label
<code>MYSTRING</code>, you can write:</p>
<pre>
MYSTRING .STR "hello"
LDA #&lt;MYSTRING
STA $00
lda #&gt;MYSTRING
STA $01
</pre>
<p>The format editor allows you to choose which part of the symbol's
value to use. If the value doesn't match exactly, an adjustment will
be applied.</p>
<h3><a name="weak-refs">Weak References</a></h3>
<p>Symbolic references in operands are "weak references". If the named
symbol exists, the reference is used. If the symbol can't be found, the
operand is formatted in hex instead.</p>
<p>It's important to know this when editing a project. Consider the
following trivial chunk of code:
<pre>
1000: 4c0310 JMP $1003
1003: ea NOP
</pre>
<p>When you load it into SourceGen, it will be formatted like this:</p>
<pre>
.ORG $1000
JMP L1003
L1003 NOP
</pre>
<p>The analyzer found the JMP operand, and created an auto label for
address $1003. It then created a weak reference to "L1003" in the JMP
operand.</p>
<p>If you edit the JMP instruction's operand to use the symbol "FOO", the
results are probably not what you want:</p>
<pre>
.ORG $1000
JMP $1003
NOP
</pre>
<p>This happened because you added a weak reference to "FOO" in the operand,
but the label doesn't exist. The operand is formatted as hex. Because
there's no longer a reference to L1003, SourceGen removed the auto-label
as well.</p>
<p>If you set the label "FOO" on the NOP instruction, you'll see what you
probably wanted:</p>
<pre>
.ORG $1000
JMP FOO
FOO NOP
</pre>
<p>You don't actually need the explicit reference in the JMP instruction.
If you edit the JMP operand and set it back to "Default", the code will
still look the same. This is because SourceGen identified the numeric
reference, and automatically added a symbolic reference to the label on
the NOP instruction.</p>
<p>However, suppose you didn't actually want FOO as the operand label.
You can create a project symbol, BAR with the value $1003, and then edit
the operand to reference BAR instead. Your code would then look like:</p>
<pre>
BAR .EQ $1003
.ORG $1000
JMP BAR
FOO NOP
</pre>
<p>If you change the value of BAR in the project symbol file, the operand
will continue to refer to it, but with an adjustment. For example, if
you changed BAR from $1003 to $1007, the code would become:</p>
<pre>
BAR .EQ $1007
.ORG $1000
JMP BAR-4
FOO NOP
</pre>
<p>If you rename a label, all references to that label are updated. For
numeric references that happens implicitly. For explicit operand
references, the weak references are updated individually. (Modern IDEs
call this "refactoring".)</p>
<p>If you remove a label, all of the numeric references to it will
reference something else, probably a new auto label. Weak references
to the symbol will break and be formatted as hex, but will not be
removed. Similarly, removing symbols from a platform or project file
will break the reference but won't modify the operands.</p>
<h3><a name="symbol-parts">Parts and Adjustments</a></h3>
<p>Sometimes you want to use part of a label, or adjust the value slightly.
(I use "adjustment" rather than "offset" to avoid confusing it with file
offsets.) Consider the following example:</p>
<pre>
1000: a910 LDA #$10
1002: 48 PHA
1003: a906 LDA #$06
1005: 48 PHA
1006: 60 RTS
1007: 4c3aff JMP $ff3a
</pre>
<p>This pushes the address of the JMP instruction ($1007) onto the stack,
and jumps to it with the RTS instruction. However, RTS requires the
address of the byte before the target instruction, so we actually push
$1006.</p>
<p>The disassembler won't know that offset $1007 is code because nothing
appears to reference it. After adding a code hint at $1007, the project
looks like this:</p>
<pre>
LDA #$10
PHA
LDA #$06
PHA
RTS
JMP $ff3a
</pre>
<p>We set a label called "NEXT" on the JMP instruction, and then edit
the two LDA instructions to reference the high and low parts, yielding:</p>
<pre>
.ORG $1000
LDA #&gt;NEXT
PHA
LDA #&lt;NEXT-1
PHA
RTS
NEXT JMP $ff3a
</pre>
<p>SourceGen will adjust label values by whatever amount is required to
generate the original value. If the adjustment seems wrong, make sure
you're selecting the right part of the symbol.</p>
<p>Different assemblers use different syntaxes to form expressions. This
is particularly noticeable in 65816 code. You can adjust how it appears
on-screen from the app settings.</p>
<h3><a name="nearby-targets">Automatic Use of Nearby Targets</a></h3>
<p>Sometimes you want to use a symbol that doesn't match up with the
operand. SourceGen tries to anticipate situations where that might be
the case, and apply adjustments for you.</p>
<p>Suppose you have the following:</p>
<pre>
.ORG $1000
LDA #$00
STA L1010
LDA #$20
STA L1011
LDA #$e1
STA L1012
RTS
L1010 .DD1 $00
L1011 .DD1 $00
L1012 .DD1 $00
</pre>
<p>Showing stores to three different labeled addresses is fine, but
the code is actually setting up a single 24-bit address. For clarity,
you'd like the output to reflect the fact that it's a single, multi-byte
variable. So, if you set a label at $1010, SourceGen removes the
nearby auto labels, and sets the numeric references to use your label:
<pre>
.ORG $1000
LDA #$00
STA DATA
LDA #$20
STA DATA+1
LDA #$e1
STA DATA+2
RTS
DATA .DD1 $00
.DD1 $00
.DD1 $00
</pre>
<p>If you decide that you really wanted each store to have its own
label, you can set labels on the other two addresses. SourceGen won't
search for alternate labels if the numeric reference target has a
user-defined label.</p>
<p>This is also used for self-modifying code. For example:</p>
<pre>
1000: a9ff LDA #$ff
1002: 8d0610 STA $1006
1005: 4900 EOR #$00
</pre>
<p>The above changes the <code>EOR #$00</code> instruction to
<code>EOR #$ff</code>. The operand target is $1006, but we can't
put a label there because it's in the middle of the instruction. So
SourceGen puts a label at $1005 and adjusts it:</p>
<pre>
LDA #$ff
STA L1005+1
L1005 EOR #$00
</pre>
<p>If you really don't like the way this works, you can disable the
search for alternate targets entirely from the
<a href="settings.html#project-properties">project properties</a>.
Self-modifying code will always be adjusted because of the limitation
on mid-instruction labels.</p>
<h2><a name="width-disambiguation">Width Disambiguation</a></h2>
<p>It's possible to interpret certain instructions in multiple ways.
For example, "LDA $0000" might be an absolute load from a 16-bit
address, or it might be a direct page load from an 8-bit address.
Humans can infer from the fact that it was written with a 4-digit address
that it's meant to be absolute, but assemblers often treat operands
purely as numbers, and would just see "LDA 0". Common practice is to
use the shortest instruction possible.</p>
<p>Every assembler seems to address the problem in a slightly different
way. Some use opcode suffixes, others use operand prefixes, some
allow both. You can configure how they appear in the
<a href="settings.html#app-settings">application settings</a>.</p>
<p>SourcGen will only add width disambiguators to opcodes or operands when
they are needed, with one exception: the opcode suffix for long
(24-bit address) operations is always applied. This is done because some
assemblers require it, insisting on "LDAL" rather than "LDA" for an
absolute long load, and because it can make 65816 code easier to read.</p>
<h2><a name="pseudo-ops">Data and Directive Pseudo-Opcodes</a></h2>
<p>There are only three assembler directives that appear in the code list:</p>
<ul>
<li>.EQ - defines a symbol's value. These are generated automatically
when an operand that matches a platform or project symbol is found.</li>
<li>.ORG - changes the target address.</li>
<li>.RWID - specifies the width of the accumulator and index registers
(65816 only). Note this doesn't change the actual width, just tells
the assembler that the width has changed.</li>
</ul>
<p>Every data item is represented by a pseudo-op. Some of them may
represent hundreds of bytes and span multiple lines.</p>
<ul>
<li>.DD1, .DD2, .DD3, .DD4 - basic "define data" op. A 1-4 byte
little-endian value.</li>
<li>.DBD2, .DBD3, .DBD4 - "define big-endian data". 2-4 bytes of
big-endian data.</li>
<li>.BULK - data packed in as compact a form as the assembler allows.
Useful for chunks of graphics data.</li>
<li>.FILL - a series of identical bytes. The operand
is the byte count, followed by the byte value.
</ul>
<p>In addition, several pseudo-ops are defined for string constants:</p>
<ul>
<li>.STR - basic ASCII string.</li>
<li>.RSTR - string in reverse order.</li>
<li>.ZSTR - null-terminated string.</li>
<li>.DSTR - Dextral Character Inverted string. The high bit of the
last byte is flipped.</li>
<li>.L1STR - string prefixed with a length byte.</li>
<li>.L2STR - string prefixed with a length word.</li>
</ul>
<p>If the characters have their high bits set -- commonly referred to
as "high ASCII" -- an upward arrow will be added to the pseudo-op. How
these strings are generated into assembly source varies.</p>
<p>You can configure these to look more like what your favorite assembler
uses in the
<a href="settings.html#app-settings">application settings</a>.</p>
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