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manual:chapter5:asm [2019/12/03 10:26]
claudio [Instruction set and syntax] |
manual:chapter5:asm [2021/09/29 05:58] (current)
jojo1973 [Simple assignments with operators] |
| In these cases a compact subset of instructions, with a different syntax and based on the manipulation of a small number of global registers, may achieve greater clarity; this subset of the language, given its compact format, is called **Assembly-like Instruction Set**. | In these cases a compact subset of instructions, with a different syntax and based on the manipulation of a small number of global registers, may achieve greater clarity; this subset of the language, given its compact format, is called **Assembly-like Instruction Set**. |
| |
| The Assembly-like Instruction Set is not meant as a separate programming language neither its feature are intended to be sandboxed in exclusive environments: its statements can be freely intermingled with **newRPL** commands and to suit anyone's programming style. | The Assembly-like Instruction Set is not meant as a separate programming language neither its features are intended to be sandboxed in exclusive environments: its statements can be freely intermingled with **newRPL** commands to suit anyone's programming style. |
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| ==== Registers and pseudo-registers ==== | ==== Registers and pseudo-registers ==== |
| | ::: | ::: | ''ASIN'' | ::: | ::: | ''MAX'' | | | ::: | ::: | ''ASIN'' | ::: | ::: | ''MAX'' | |
| | ::: | ::: | ''ACOS'' | ::: | ::: | ''RND'' | | | ::: | ::: | ''ACOS'' | ::: | ::: | ''RND'' | |
| | ::: | ::: | ''ATAN'' | ::: | ::: | | | | ::: | ::: | ''ATAN'' | ::: | ::: | ''CLR'' | |
| | ::: | ::: | ''SINH'' | ::: | ::: | ::: | | | ::: | ::: | ''SINH'' | ::: | ::: | | |
| | ::: | ::: | ''COSH'' | ::: | ::: | ::: | | | ::: | ::: | ''COSH'' | ::: | ::: | | |
| | ::: | ::: | ''TANH'' | ::: | ::: | ::: | | | ::: | ::: | ''TANH'' | ::: | ::: | ::: | |
| | ::: | ::: | ''ASINH'' | ::: | ::: | ::: | | | ::: | ::: | ''ASINH'' | ::: | ::: | ::: | |
| * an optional //assignment operator// (''='', ''+='', ''-='', ''*='' or ''/=''); | * an optional //assignment operator// (''='', ''+='', ''-='', ''*='' or ''/=''); |
| * a //math operator//, a //math function// or a //data manipulation command//: operators are __infix__, functions and commands are __prefix__; | * a //math operator//, a //math function// or a //data manipulation command//: operators are __infix__, functions and commands are __prefix__; |
| * 1 or 2 arguments to the operator or function. Arguments can be either a (pseudo-)register (''A''-''H'', ''S1''-''S7''), a reference (''R'') or a literal. The context makes clear if the arguments are to be interpreted as //direct// (e.g. register ''A'') or //indirect// (e.g. the stack level referenced by register ''A''). | * 1 or 2 arguments to the operator or function. Arguments can be either a (pseudo-)register (''A''-''H'', ''S1''-''S7''), a reference (''R'') or a literal. |
| |
| * **Commands**, which may be | * **Commands**, which may be |
| * a //flow control// command, followed by the condition to be tested; | * a //flow control// command, followed by the condition to be tested; |
| * a //data manipulation// command, followed by two arguments defining the extent of the manipulation; | * a //data manipulation// command, followed by two arguments defining the extent of the manipulation; |
| * arguments can be either a register (''A''-''H'', ''S1''-''S7''), a reference (''R'') or a literal. The context makes clear if the arguments are to be interpreted as //direct// (e.g. register ''A'') or //indirect// (e.g. the stack level referenced by register ''A''). | * arguments can be either a register (''A''-''H'', ''S1''-''S7''), a reference (''R'') or a literal. |
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| ==== Simple assignments with operators ==== | ==== Simple assignments with operators ==== |
| |
| | '':A=B+#1'' | Add ''1'' to the value of register ''B'' and assign the result to register ''A'' | | | '':A=B+#1'' | Add ''1'' to the value of register ''B'' and assign the result to register ''A'' | |
| | '':E=R { 1 2 3 }'' | Assign the list ''{ 1 2 3 }'' to register ''E'' | | | '':E=R { 1 2 3 }'' | Store the list ''{ 1 2 3 }'' in register ''E'' | |
| | '':P=A'' | Push the value of register ''A'' to the stack | | | '':P=A'' | Push the value of register ''A'' to the stack | |
| | '':A=S2'' '':S2=S1'' '':S1=A'' | Swap stack level 1 with level 2 using register ''A'' as temporary storage. An error is raised if the stack contains less than 2 levels | | | '':A=S2'' '':S2=S1'' '':S1=A'' | Swap stack level 1 with level 2 using register ''A'' as temporary storage. An error is raised if the stack contains less than 2 levels | |
| | '':C+=B^#2'' | Square the value register ''B'' and adds the result to register ''C'' | | | '':C+=B^#2'' | Square the value register ''B'' and adds the result to register ''C'' | |
| | | '':B=R^#2 π'' | Assign ''%%'%%π^2%%'%%'' to register B. This example shows that register ''R'' must not necessarily be the second argument of a binary operator | |
| |
| ==== Assignment with math functions ==== | ==== Assignment with math functions ==== |
| | '':D=ATANH.R %%'e^2'%%'' | Assign the hyperbolic arctangent of ''%%'e^2'%%'' to register ''D'' | | | '':D=ATANH.R %%'e^2'%%'' | Assign the hyperbolic arctangent of ''%%'e^2'%%'' to register ''D'' | |
| |
| ==== Testing ==== | ==== Tests ==== |
| | |
| | Test instructions will, when the result is not stored or assigned to any register, affect two system flags: flag [[manual:appendix:flags#flag-58|-58]] if the result of the test was zero (in the case of ''CMP'', if the two arguments are equal) and flag [[manual:appendix:flags#flag-59|-59]] if the result is negative (in the case of ''CMP'', when the first argument is less than the second). |
| | |
| | The ''CMP'' command is equivalent to the **newRPL** ''[[manual:chapter6:operators:cmd_ovr_cmp|CMP]]'' operator and accepts the same type of arguments. |
| |
| | '':CMP.A.#1'' | Compare register ''A'' and literal ''1'', setting internal flags accordingly | | | '':CMP.A.#1'' | Compare register ''A'' and literal ''1'', setting internal flags accordingly | |
| | | '':C=CMP.A.#1'' | Compare register ''A'' and literal ''1'', store the result of the comparison in ''C''. In this case internal flags will **not** be set. | |
| | | '':AND.A.#1'' | Logical ''AND'' between ''A'' and literal ''1'' (always true), therefore resulting in ''0'' (false) if ''A'' is false, true otherwise. Internal flags will be set accordingly. | |
| | | '':C=AND.A.#1'' | Same as above, store the result of the test (true/false) in ''C''. In this case internal flags will **not** be set. | |
| |
| The ''CMP'' command is equivalent to the **newRPL** ''[[manual:chapter6:operators:cmd_ovr_cmp|CMP]]'' operator and accepts the same type of arguments, but instead of returning a value representing the result of the comparison it merely sets two system flags: flag [[manual:appendix:flags#flag-58|-58]] if the two arguments are equal and flag [[manual:appendix:flags#flag-59|-59]] if the first argument is less than the second. | |
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| ==== Flow control ==== | ==== Flow control ==== |
| | ''AL'' | Always | --- | --- | | | ''AL'' | Always | --- | --- | |
| | ''LT'' | Less Than | --- | Set | | | ''LT'' | Less Than | --- | Set | |
| | ''EQ'' | Equals | Set | --- | | | ''EQ'' or ''Z'' | Equals | Set | --- | |
| | ''LTE'' | Less Than or Equals | --- | Set | | | ''LE'' | Less Than or Equals | --- | Set | |
| | ::: | ::: | Set | --- | | | ::: | ::: | Set | --- | |
| | ''NA'' | Never | --- | --- | | | ''NA'' | Never | --- | --- | |
| | ''GTE'' | Greater Than or Equals | --- | Clear | | | ''GE'' | Greater Than or Equals | --- | Clear | |
| | ''NE'' | Not Equals | Clear | --- | | | ''NE'' or ''NZ'' | Not Equals | Clear | --- | |
| | ''GT'' | Greater Than | Clear | Clear | | | ''GT'' | Greater Than | Clear | Clear | |
| |
| ---- | ---- |
| |
| | '':SKIP.EQ'' | Skip next instruction if the result of last comparison was //Equals// | | | '':SKIP.EQ'' | Skip next instruction if the state of the flags was //Equals// | |
| | '':LOOP.LTE'' | Must be followed by a program ''« ... »'' or a secondary '':: ... ;''. Repeat the object that follows while the result of the last comparison is //Less Than or Equals//. Notice the program or secondary that follows **must** update the internal flags with a '':CMP.[Y].[Z]'' statement or it will loop indefintely | | | '':LOOP.LE'' | Must be followed by a program ''« ... »'' or a secondary '':: ... ;''. Repeat the object that follows while the state of the flags is //Less Than or Equals//. Notice the program or secondary that follows **must** update the internal flags with a '':CMP.[Y].[Z]'' or other test statement or it will loop indefinitely | |
| | '':FPUSH.GT'' | Push True (''1'') to the stack if the result of the last comparison is //Greater Than//, otherwise push False (''0'') | | | '':A=CHK.GT'' | Results in true (''1'') if the state of flags is //Greater Than//, otherwise results in False (''0''). Result may be stored into a register or pseudo-register. If the result is not stored, flags will be affected accordingly | |
| |
| The ''FPUSH'' command is useful to combine assembly-like statements into **newRPL** flow control structures. For example<code> | The ''CHK'' command is useful to combine assembly-like statements into **newRPL** flow control structures. For example<code> |
| « IF | « IF |
| :CMP.A.#0 | :CMP.A.#3 @@ COMPARE A WITH 3 |
| :FPUSH.EQ | :P=CHK.EQ @@ AND CHECK IF IT'S EQUAL, PUSHING TRUE/FALSE TO THE STACK |
| THEN | THEN |
| ... | ... |
| | '':PUSH.A.#3'' | Reverse of '':POP''. In this example will do '':P=C'', '':P=B'' and '':P=A'' | | | '':PUSH.A.#3'' | Reverse of '':POP''. In this example will do '':P=C'', '':P=B'' and '':P=A'' | |
| | '':RPUSH.A.#3'' | Reverse of '':RPOP''. In this example will do '':P=A'', '':P=B'', and '':P=C'' | | | '':RPUSH.A.#3'' | Reverse of '':RPOP''. In this example will do '':P=A'', '':P=B'', and '':P=C'' | |
| | | '':CLR.A.#3'' | Set registers to zero (clear) starting with ''A'', and as many registers as requested. In this example will do '':A=0'', '':B=0'' and '':C=0'' | |
| |
| ==== Example code ==== | ==== Example code ==== |
| -103 SF @ Complex results | -103 SF @ Complex results |
| :A=RPOP.S1.#3 @ Store coefficients in registers | :A=RPOP.S1.#3 @ Store coefficients in registers |
| :CMP.A.#0 :FPUSH.EQ @ a=0? Push test on the stack | :AND.A.C @ Are either zero? |
| :CMP.C.#0 :FPUSH.EQ @ c=0? Push test on the stack | :SKIP.NZ @ Skip next seco if both A and C were non-zero |
| OR @ Are either zero? | |
| :CMP.S1.#1 DROP @ Turn newRPL boolean into flags and discard it | |
| :SKIP.NE @ Skip next seco if false | |
| :: "Zero Input Invalid" | :: "Zero Input Invalid" |
| DOERR @ Abort with error | DOERR @ Abort with error |
| ; | ; |
| :P=#0-B @ Push -B on stack | :D=#0-B @ -B |
| DUP SQ @ -B, B^2 | :E=B*B @ B^2 |
| 4 :S1*=A :S1*=C @ -B, B^2, 4*A*C | :F=#4*A :F*=C @ 4*A*C |
| - √ @ -B, √(B^2-4*A*C) | :E-=F :E=SQRT.E @ √(B^2-4*A*C) |
| :P=B SIGN * - @ -B-SIGN(B)*√(B^2-4*A*C) | |
| 2 / :S1/=A @ (-B-SIGN(B)*√(B^2-4*A*C))/2/A is R1, the largest root in absolute value | :CMP.B.#0 |
| :P=C :S1/=A @ R1, C/A | :SKIP.GE :F=D+E @ -B+√(B^2-4*A*C) when B<=0 |
| | :SKIP.LT :F=D-E @ -B-√(B^2-4*A*C) when B>0 |
| | |
| | :E=A*#2 @ 2*A |
| | :P=F/E @ (-B-SIGN(B)*√(B^2-4*A*C))/2/A is R1, the largest root in absolute value |
| | :P=C/A @ R1, C/A |
| :S1/=S2 @ C/(R1*A) is R2, the other root | :S1/=S2 @ C/(R1*A) is R2, the other root |
| » | » |
| :F*=A @ F='(y2-y1)*(X-x1)' | :F*=A @ F='(y2-y1)*(X-x1)' |
| :B-=F @ B='(Y-y1)*(x2-x1)-(y2-y1)*(X-x1)' | :B-=F @ B='(Y-y1)*(x2-x1)-(y2-y1)*(X-x1)' |
| :PUSH.B.#1 @ Push result on the stack | :P=B @ Push result on the stack |
| » | » |
| » | » |
| </code> | </code> |