gcc/libgcc/config/msp430/lib2hw_mul.S
Jakub Jelinek cbe34bb5ed Update copyright years.
From-SVN: r243994
2017-01-01 13:07:43 +01:00

370 lines
13 KiB
ArmAsm

; Copyright (C) 2014-2017 Free Software Foundation, Inc.
; Contributed by Red Hat.
;
; This file is free software; you can redistribute it and/or modify it
; under the terms of the GNU General Public License as published by the
; Free Software Foundation; either version 3, or (at your option) any
; later version.
;
; This file is distributed in the hope that it will be useful, but
; WITHOUT ANY WARRANTY; without even the implied warranty of
; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
; General Public License for more details.
;
; Under Section 7 of GPL version 3, you are granted additional
; permissions described in the GCC Runtime Library Exception, version
; 3.1, as published by the Free Software Foundation.
;
; You should have received a copy of the GNU General Public License and
; a copy of the GCC Runtime Library Exception along with this program;
; see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
; <http://www.gnu.org/licenses/>.
;; Macro to start a multiply function. Each function has three
;; names, and hence three entry points - although they all go
;; through the same code. The first name is the version generated
;; by GCC. The second is the MSP430 EABI mandated name for the
;; *software* version of the function. The third is the EABI
;; mandated name for the *hardware* version of the function.
;;
;; Since we are using the hardware and software names to point
;; to the same code this effectively means that we are mapping
;; the software function onto the hardware function. Thus if
;; the library containing this code is linked into an application
;; (before the libgcc.a library) *all* multiply functions will
;; be mapped onto the hardware versions.
;;
;; We construct each function in its own section so that linker
;; garbage collection can be used to delete any unused functions
;; from this file.
.macro start_func gcc_name eabi_soft_name eabi_hard_name
.pushsection .text.\gcc_name,"ax",@progbits
.p2align 1
.global \eabi_hard_name
.type \eabi_hard_name , @function
\eabi_hard_name:
.global \eabi_soft_name
.type \eabi_soft_name , @function
\eabi_soft_name:
.global \gcc_name
.type \gcc_name , @function
\gcc_name:
PUSH.W sr ; Save current interrupt state
DINT ; Disable interrupts
NOP ; Account for latency
.endm
;; End a function started with the start_func macro.
.macro end_func name
#ifdef __MSP430X_LARGE__
POP.W sr
RETA
#else
RETI
#endif
.size \name , . - \name
.popsection
.endm
;; Like the start_func macro except that it is used to
;; create a false entry point that just jumps to the
;; software function (implemented elsewhere).
.macro fake_func gcc_name eabi_soft_name eabi_hard_name
.pushsection .text.\gcc_name,"ax",@progbits
.p2align 1
.global \eabi_hard_name
.type \eabi_hard_name , @function
\eabi_hard_name:
.global \gcc_name
.type \gcc_name , @function
\gcc_name:
#ifdef __MSP430X_LARGE__
BRA \eabi_soft_name
#else
BR \eabi_soft_name
#endif
.size \gcc_name , . - \gcc_name
.popsection
.endm
.macro mult16 OP1, OP2, RESULT
;* * 16-bit hardware multiply: int16 = int16 * int16
;*
;* - Operand 1 is in R12
;* - Operand 2 is in R13
;* - Result is in R12
;*
;* To ensure that the multiply is performed atomically, interrupts are
;* disabled upon routine entry. Interrupt state is restored upon exit.
;*
;* Registers used: R12, R13
;*
;* Macro arguments are the memory locations of the hardware registers.
MOV.W r12, &\OP1 ; Load operand 1 into multiplier
MOV.W r13, &\OP2 ; Load operand 2 which triggers MPY
MOV.W &\RESULT, r12 ; Move result into return register
.endm
.macro mult1632 OP1, OP2, RESULT_LO, RESULT_HI
;* * 16-bit hardware multiply with a 32-bit result:
;* int32 = int16 * int16
;* uint32 = uint16 * uint16
;*
;* - Operand 1 is in R12
;* - Operand 2 is in R13
;* - Result is in R12, R13
;*
;* To ensure that the multiply is performed atomically, interrupts are
;* disabled upon routine entry. Interrupt state is restored upon exit.
;*
;* Registers used: R12, R13
;*
;* Macro arguments are the memory locations of the hardware registers.
MOV.W r12, &\OP1 ; Load operand 1 into multiplier
MOV.W r13, &\OP2 ; Load operand 2 which triggers MPY
MOV.W &\RESULT_LO, r12 ; Move low result into return register
MOV.W &\RESULT_HI, r13 ; Move high result into return register
.endm
.macro mult32 OP1, OP2, MAC_OP1, MAC_OP2, RESULT_LO, RESULT_HI
;* * 32-bit hardware multiply with a 32-bit result using 16 multiply and accumulate:
;* int32 = int32 * int32
;*
;* - Operand 1 is in R12, R13
;* - Operand 2 is in R14, R15
;* - Result is in R12, R13
;*
;* To ensure that the multiply is performed atomically, interrupts are
;* disabled upon routine entry. Interrupt state is restored upon exit.
;*
;* Registers used: R12, R13, R14, R15
;*
;* Macro arguments are the memory locations of the hardware registers.
MOV.W r12, &\OP1 ; Load operand 1 Low into multiplier
MOV.W r14, &\OP2 ; Load operand 2 Low which triggers MPY
MOV.W r12, &\MAC_OP1 ; Load operand 1 Low into mac
MOV.W &\RESULT_LO, r12 ; Low 16-bits of result ready for return
MOV.W &\RESULT_HI, &\RESULT_LO; MOV intermediate mpy high into low
MOV.W r15, &\MAC_OP2 ; Load operand 2 High, trigger MAC
MOV.W r13, &\MAC_OP1 ; Load operand 1 High
MOV.W r14, &\MAC_OP2 ; Load operand 2 Lo, trigger MAC
MOV.W &\RESULT_LO, r13 ; Upper 16-bits result ready for return
.endm
.macro mult32_hw OP1_LO OP1_HI OP2_LO OP2_HI RESULT_LO RESULT_HI
;* * 32-bit hardware multiply with a 32-bit result
;* int32 = int32 * int32
;*
;* - Operand 1 is in R12, R13
;* - Operand 2 is in R14, R15
;* - Result is in R12, R13
;*
;* To ensure that the multiply is performed atomically, interrupts are
;* disabled upon routine entry. Interrupt state is restored upon exit.
;*
;* Registers used: R12, R13, R14, R15
;*
;* Macro arguments are the memory locations of the hardware registers.
MOV.W r12, &\OP1_LO ; Load operand 1 Low into multiplier
MOV.W r13, &\OP1_HI ; Load operand 1 High into multiplier
MOV.W r14, &\OP2_LO ; Load operand 2 Low into multiplier
MOV.W r15, &\OP2_HI ; Load operand 2 High, trigger MPY
MOV.W &\RESULT_LO, r12 ; Ready low 16-bits for return
MOV.W &\RESULT_HI, r13 ; Ready high 16-bits for return
.endm
.macro mult3264_hw OP1_LO OP1_HI OP2_LO OP2_HI RES0 RES1 RES2 RES3
;* * 32-bit hardware multiply with a 64-bit result
;* int64 = int32 * int32
;* uint64 = uint32 * uint32
;*
;* - Operand 1 is in R12, R13
;* - Operand 2 is in R14, R15
;* - Result is in R12, R13, R14, R15
;*
;* To ensure that the multiply is performed atomically, interrupts are
;* disabled upon routine entry. Interrupt state is restored upon exit.
;*
;* Registers used: R12, R13, R14, R15
;*
;* Macro arguments are the memory locations of the hardware registers.
MOV.W r12, &\OP1_LO ; Load operand 1 Low into multiplier
MOV.W r13, &\OP1_HI ; Load operand 1 High into multiplier
MOV.W r14, &\OP2_LO ; Load operand 2 Low into multiplier
MOV.W r15, &\OP2_HI ; Load operand 2 High, trigger MPY
MOV.W &\RES0, R12 ; Ready low 16-bits for return
MOV.W &\RES1, R13 ;
MOV.W &\RES2, R14 ;
MOV.W &\RES3, R15 ; Ready high 16-bits for return
.endm
;; EABI mandated names:
;;
;; int16 __mspabi_mpyi (int16 x, int16 y)
;; Multiply int by int.
;; int16 __mspabi_mpyi_hw (int16 x, int16 y)
;; Multiply int by int. Uses hardware MPY16 or MPY32.
;; int16 __mspabi_mpyi_f5hw (int16 x, int16 y)
;; Multiply int by int. Uses hardware MPY32 (F5xx devices and up).
;;
;; int32 __mspabi_mpyl (int32 x, int32 y);
;; Multiply long by long.
;; int32 __mspabi_mpyl_hw (int32 x, int32 y)
;; Multiply long by long. Uses hardware MPY16.
;; int32 __mspabi_mpyl_hw32 (int32 x, int32 y)
;; Multiply long by long. Uses hardware MPY32 (F4xx devices).
;; int32 __mspabi_mpyl_f5hw (int32 x, int32 y)
;; Multiply long by long. Uses hardware MPY32 (F5xx devices and up).
;;
;; int64 __mspabi_mpyll (int64 x, int64 y)
;; Multiply long long by long long.
;; int64 __mspabi_mpyll_hw (int64 x, int64 y)
;; Multiply long long by long long. Uses hardware MPY16.
;; int64 __mspabi_mpyll_hw32 (int64 x, int64 y)
;; Multiply long long by long long. Uses hardware MPY32 (F4xx devices).
;; int64 __mspabi_mpyll_f5hw (int64 x, int64 y)
;; Multiply long long by long long. Uses hardware MPY32 (F5xx devices and up).
;;
;; int32 __mspabi_mpysl (int16 x, int16 y)
;; Multiply int by int; result is long.
;; int32 __mspabi_mpysl_hw(int16 x, int16 y)
;; Multiply int by int; result is long. Uses hardware MPY16 or MPY32
;; int32 __mspabi_mpysl_f5hw(int16 x, int16 y)
;; Multiply int by int; result is long. Uses hardware MPY32 (F5xx devices and up).
;;
;; int64 __mspabi_mpysll(int32 x, int32 y)
;; Multiply long by long; result is long long.
;; int64 __mspabi_mpysll_hw(int32 x, int32 y)
;; Multiply long by long; result is long long. Uses hardware MPY16.
;; int64 __mspabi_mpysll_hw32(int32 x, int32 y)
;; Multiply long by long; result is long long. Uses hardware MPY32 (F4xx devices).
;; int64 __mspabi_mpysll_f5hw(int32 x, int32 y)
;; Multiply long by long; result is long long. Uses hardware MPY32 (F5xx devices and up).
;;
;; uint32 __mspabi_mpyul(uint16 x, uint16 y)
;; Multiply unsigned int by unsigned int; result is unsigned long.
;; uint32 __mspabi_mpyul_hw(uint16 x, uint16 y)
;; Multiply unsigned int by unsigned int; result is unsigned long. Uses hardware MPY16 or MPY32
;; uint32 __mspabi_mpyul_f5hw(uint16 x, uint16 y)
;; Multiply unsigned int by unsigned int; result is unsigned long. Uses hardware MPY32 (F5xx devices and up).
;;
;; uint64 __mspabi_mpyull(uint32 x, uint32 y)
;; Multiply unsigned long by unsigned long; result is unsigned long long.
;; uint64 __mspabi_mpyull_hw(uint32 x, uint32 y)
;; Multiply unsigned long by unsigned long; result is unsigned long long. Uses hardware MPY16
;; uint64 __mspabi_mpyull_hw32(uint32 x, uint32 y)
;; Multiply unsigned long by unsigned long; result is unsigned long long. Uses hardware MPY32 (F4xx devices).
;; uint64 _ _mspabi_mpyull_f5hw(uint32 x, uint32 y)
;; Multiply unsigned long by unsigned long; result is unsigned long long. Uses hardware MPY32 (F5xx devices and up)
.set MPY_OP1, 0x0130
.set MPY_OP1_S, 0x0132
.set MAC_OP1, 0x0134
.set MPY_OP2, 0x0138
.set MAC_OP2, 0x0138
.set RESULT_LO, 0x013A
.set RESULT_HI, 0x013C
#if defined MUL_16
;; First generation MSP430 hardware multiplies ...
start_func __mulhi2 __mspabi_mpyi __mspabi_mpyi_hw
mult16 MPY_OP1, MPY_OP2, RESULT_LO
end_func __mulhi2
start_func __mulsihi2 __mspabi_mpysl __mspabi_mpysl_hw
mult1632 MPY_OP1_S, MPY_OP2, RESULT_LO, RESULT_HI
end_func __mulsihi2
start_func __umulsihi2 __mspabi_mpyul _mspabi_mpyul_hw
mult1632 MPY_OP1, MPY_OP2, RESULT_LO, RESULT_HI
end_func __umulsihi2
start_func __mulsi2 __mspabi_mpyl __mspabi_mpyl_hw
mult32 MPY_OP1, MPY_OP2, MAC_OP1, MAC_OP2, RESULT_LO, RESULT_HI
end_func __mulsi2
;; FIXME: We do not have hardware implementations of these
;; routines, so just jump to the software versions instead.
fake_func __muldisi2 __mspabi_mpysll __mspabi_mpysll_hw
fake_func __umuldisi2 __mspabi_mpyull __mspabi_mpyull_hw
fake_func __muldi3 __mspabi_mpyll __mspabi_mpyll_hw
#elif defined MUL_32
;; Second generation MSP430 hardware multiplies ...
start_func __mulhi2 __mspabi_mpyi __mspabi_mpyi_hw
mult16 MPY_OP1, MPY_OP2, RESULT_LO
end_func __mulhi2
start_func __mulsihi2 __mspabi_mpysl __mspabi_mpysl_hw
mult1632 MPY_OP1_S, MPY_OP2, RESULT_LO, RESULT_HI
end_func __mulsihi2
start_func __umulsihi2 __mspabi_mpyul _mspabi_mpyul_hw
mult1632 MPY_OP1, MPY_OP2, RESULT_LO, RESULT_HI
end_func __umulsihi2
start_func __mulsi2_hw32 __mspabi_mpyl __mspabi_mpyl_hw32
mult32_hw 0x0140, 0x0142, 0x0150, 0x0152, 0x0154, 0x0156
end_func __mulsi2_hw32
start_func __muldisi2 __mspabi_mpysll __mspabi_mpysll_hw32
mult3264_hw 0x0144, 0x146, 0x0150, 0x0152, 0x0154, 0x0156, 0x0158, 0x015A
end_func __muldisi2
start_func __umuldisi2 __mspabi_mpyull __mspabi_mpyull_hw32
mult3264_hw 0x0140, 0x142, 0x0150, 0x0152, 0x0154, 0x0156, 0x0158, 0x015A
end_func __umuldisi2
;; FIXME: Add a hardware version of this function.
fake_func __muldi3 __mspabi_mpyll __mspabi_mpyll_hw32
#elif defined MUL_F5
/* The F5xxx series of MCUs support the same 16-bit and 32-bit multiply
as the second generation hardware, but they are accessed from different
memory registers. */
start_func __mulhi2_f5 __mspabi_mpyi __mspabi_mpyi_f5hw
mult16 0x04C0, 0x04C8, 0x04CA
end_func __mulhi2_f5
start_func __mulsihi2 __mspabi_mpysl __mspabi_mpysl_f5hw
mult1632 0x04C2, 0x04C8, 0x04CA, 0x04CC
end_func __mulsihi2
start_func __umulsihi2 __mspabi_mpyul _mspabi_mpyul_f5hw
mult1632 0x04C0, 0x04C8, 0x04CA, 0x04CC
end_func __umulsihi2
start_func __mulsi2_f5 __mspabi_mpyl __mspabi_mpyl_f5hw
mult32_hw 0x04D0, 0x04D2, 0x04E0, 0x04E2, 0x04E4, 0x04E6
end_func __mulsi2_f5
start_func __muldisi2 __mspabi_mpysll __mspabi_mpysll_f5hw
mult3264_hw 0x04D4, 0x04D6, 0x04E0, 0x04E2, 0x04E4, 0x04E6, 0x04E8, 0x04EA
end_func __muldisi2
start_func __umuldisi2 __mspabi_mpyull __mspabi_mpyull_f5hw
mult3264_hw 0x04D0, 0x04D2, 0x04E0, 0x04E2, 0x04E4, 0x04E6, 0x04E8, 0x04EA
end_func __umuldisi2
;; FIXME: Add a hardware version of this function.
fake_func __muldi3 __mspabi_mpyll __mspabi_mpyll_f5hw
#else
#error MUL type not defined
#endif