/* ###################### CMSIS Support for Cortex-M4 SIMD Instructions ####################### */
/**
\defgroup intrinsic_SIMD_gr Intrinsic Functions for SIMD Instructions [only Cortex-M4 and Cortex-M7]
\brief Access to dedicated SIMD instructions.
\details
Single Instruction Multiple Data (SIMD) extensions are provided only for Cortex-M4 and Cortex-M7 cores
to simplify development of application software. SIMD extensions increase the processing capability
without materially increasing the power consumption. The SIMD extensions are completely transparent
to the operating system (OS), allowing existing OS ports to be used.
SIMD Features:
- Simultaneous computation of 2x16-bit or 4x8-bit operands
- Fractional arithmetic
- User definable saturation modes (arbitrary word-width)
- Dual 16x16 multiply-add/subtract 32x32 fractional MAC
- Simultaneous 8/16-bit select operations
- Performance up to 3.2 GOPS at 800MHz
- Performance is achieved with a "near zero" increase in power consumption on a typical implementation
\b Examples:
\b Addition: Add two values using SIMD function
\code
uint32_t add_halfwords(uint32_t val1, uint32_t val2)
{
return __SADD16(val1, val2);
}
\endcode
\b Subtraction: Subtract two values using SIMD function
\code
uint32_t sub_halfwords(uint32_t val1, uint32_t val2)
{
return __SSUB16(val1, val2);
}
\endcode
\b Multiplication: Performing a multiplication using SIMD function
\code
uint32_t dual_mul_add_products(uint32_t val1, uint32_t val2)
{
return __SMUAD(val1, val2);
}
\endcode
@{
*/
/**************************************************************************************************/
/**
\brief GE setting quad 8-bit signed addition
\details This function performs four 8-bit signed integer additions.
The GE bits of the APSR are set according to the results of the additions.
\param val1 first four 8-bit summands.
\param val2 second four 8-bit summands.
\returns
\li the addition of the first bytes from each operand, in the first byte of the return value.
\li the addition of the second bytes of each operand, in the second byte of the return value.
\li the addition of the third bytes of each operand, in the third byte of the return value.
\li the addition of the fourth bytes of each operand, in the fourth byte of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[7:0] \>= 0 then APSR.GE[0] = 1 else 0
\li if res[15:8] \>= 0 then APSR.GE[1] = 1 else 0
\li if res[23:16] \>= 0 then APSR.GE[2] = 1 else 0
\li if res[31:24] \>= 0 then APSR.GE[3] = 1 else 0
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0]
res[15:8] = val1[15:8] + val2[15:8]
res[23:16] = val1[23:16] + val2[23:16]
res[31:24] = val1[31:24] + val2[31:24]
\endcode
*/
uint32_t __SADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/** \ingroup Intrinsic_SIMD_gr
\brief Q setting quad 8-bit saturating addition
\details This function enables you to perform four 8-bit integer additions, saturating the results to
the 8-bit signed integer range -27 \<= x \<= 27 - 1.
\param val1 first four 8-bit summands.
\param val2 second four 8-bit summands.
\returns
\li the saturated addition of the first byte of each operand in the first byte of the return value.
\li the saturated addition of the second byte of each operand in the second byte of the return value.
\li the saturated addition of the third byte of each operand in the third byte of the return value.
\li the saturated addition of the fourth byte of each operand in the fourth byte of the return value.
\par
The returned results are saturated to the 16-bit signed integer range -27 \<= x \<= 27 - 1.
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0]
res[15:8] = val1[15:8] + val2[15:8]
res[23:16] = val1[23:16] + val2[23:16]
res[31:24] = val1[31:24] + val2[31:24]
\endcode
*/
uint32_t __QADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit signed addition with halved results
\details This function enables you to perform four signed 8-bit integer additions, halving the results.
\param val1 first four 8-bit summands.
\param val2 second four 8-bit summands.
\returns
\li the halved addition of the first bytes from each operand, in the first byte of the return value.
\li the halved addition of the second bytes from each operand, in the second byte of the return value.
\li the halved addition of the third bytes from each operand, in the third byte of the return value.
\li the halved addition of the fourth bytes from each operand, in the fourth byte of the return value.
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0] >> 1
res[15:8] = val1[15:8] + val2[15:8] >> 1
res[23:16] = val1[23:16] + val2[23:16] >> 1
res[31:24] = val1[31:24] + val2[31:24] >> 1
\endcode
*/
uint32_t __SHADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/** \ingroup Intrinsic_SIMD_gr
\brief GE setting quad 8-bit unsigned addition
\details This function enables you to perform four unsigned 8-bit integer additions.
The GE bits of the APSR are set according to the results.
\param val1 first four 8-bit summands for each addition.
\param val2 second four 8-bit summands for each addition.
\returns
\li the halved addition of the first bytes from each operand, in the first byte of the return value.
\li the halved addition of the second bytes from each operand, in the second byte of the return value.
\li the halved addition of the third bytes from each operand, in the third byte of the return value.
\li the halved addition of the fourth bytes from each operand, in the fourth byte of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on the results of the operation.
\par
If \em res is the return value, then:
\li if res[7:0] \>= 0x100 then APSR.GE[0] = 1 else 0
\li if res[15:8] \>= 0x100 then APSR.GE[1] = 1 else 0
\li if res[23:16] \>= 0x100 then APSR.GE[2] = 1 else 0
\li if res[31:24] \>= 0x100 then APSR.GE[3] = 1 else 0
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0]
res[15:8] = val1[15:8] + val2[15:8]
res[23:16] = val1[23:16] + val2[23:16]
res[31:24] = val1[31:24] + val2[31:24]
\endcode
*/
uint32_t __UADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit unsigned saturating addition
\details This function enables you to perform four unsigned 8-bit integer additions, saturating the
results to the 8-bit unsigned integer range 0 \< x \< 28 - 1.
\param val1 first four 8-bit summands.
\param val2 second four 8-bit summands.
\returns
\li the halved addition of the first bytes in each operand, in the first byte of the return value.
\li the halved addition of the second bytes in each operand, in the second byte of the return value.
\li the halved addition of the third bytes in each operand, in the third byte of the return value.
\li the halved addition of the fourth bytes in each operand, in the fourth byte of the return value.
\par
The results are saturated to the 8-bit unsigned integer range 0 \< x \< 28 - 1.
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0]
res[15:8] = val1[15:8] + val2[15:8]
res[23:16] = val1[23:16] + val2[23:16]
res[31:24] = val1[31:24] + val2[31:24]
\endcode
*/
uint32_t __UQADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit unsigned addition with halved results
\details This function enables you to perform four unsigned 8-bit integer additions, halving the results.
\param val1 first four 8-bit summands.
\param val2 second four 8-bit summands.
\returns
\li the halved addition of the first bytes in each operand, in the first byte of the return value.
\li the halved addition of the second bytes in each operand, in the second byte of the return value.
\li the halved addition of the third bytes in each operand, in the third byte of the return value.
\li the halved addition of the fourth bytes in each operand, in the fourth byte of the return value.
\par Operation:
\code
res[7:0] = val1[7:0] + val2[7:0] >> 1
res[15:8] = val1[15:8] + val2[15:8] >> 1
res[23:16] = val1[23:16] + val2[23:16] >> 1
res[31:24] = val1[31:24] + val2[31:24] >> 1
\endcode
*/
uint32_t __UHADD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting quad 8-bit signed subtraction
\details This function enables you to perform four 8-bit signed integer subtractions.
The GE bits in the APSR are set according to the results.
\param val1 first four 8-bit operands of each subtraction.
\param val2 second four 8-bit operands of each subtraction.
\returns
\li the subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[8:0] \>= 0 then APSR.GE[0] = 1 else 0
\li if res[15:8] \>= 0 then APSR.GE[1] = 1 else 0
\li if res[23:16] \>= 0 then APSR.GE[2] = 1 else 0
\li if res[31:24] \>= 0 then APSR.GE[3] = 1 else 0
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0]
res[15:8] = val1[15:8] - val2[15:8]
res[23:16] = val1[23:16] - val2[23:16]
res[31:24] = val1[31:24] - val2[31:24]
\endcode
*/
uint32_t __SSUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting quad 8-bit saturating subtract
\details This function enables you to perform four 8-bit integer subtractions, saturating the results
to the 8-bit signed integer range -27 \<= x \<= 27 - 1.
\param val1 first four 8-bit operands.
\param val2 second four 8-bit operands.
\returns
\li the subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par
The returned results are saturated to the 8-bit signed integer range -27 \<= x \<= 27 - 1.
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0]
res[15:8] = val1[15:8] - val2[15:8]
res[23:16] = val1[23:16] - val2[23:16]
res[31:24] = val1[31:24] - val2[31:24]
\endcode
*/
uint32_t __QSUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit signed subtraction with halved results
\details This function enables you to perform four signed 8-bit integer subtractions, halving the
results.
\param val1 first four 8-bit operands.
\param val2 second four 8-bit operands.
\returns
\li the halved subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the halved subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the halved subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the halved subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0] >> 1
res[15:8] = val1[15:8] - val2[15:8] >> 1
res[23:16] = val1[23:16] - val2[23:16] >> 1
res[31:24] = val1[31:24] - val2[31:24] >> 1
\endcode
*/
uint32_t __SHSUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting quad 8-bit unsigned subtract
\details This function enables you to perform four 8-bit unsigned integer subtractions.
The GE bits in the APSR are set according to the results.
\param val1 first four 8-bit operands.
\param val2 second four 8-bit operands.
\returns
\li the subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[8:0] \>= 0 then APSR.GE[0] = 1 else 0
\li if res[15:8] \>= 0 then APSR.GE[1] = 1 else 0
\li if res[23:16] \>= 0 then APSR.GE[2] = 1 else 0
\li if res[31:24] \>= 0 then APSR.GE[3] = 1 else 0
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0]
res[15:8] = val1[15:8] - val2[15:8]
res[23:16] = val1[23:16] - val2[23:16]
res[31:24] = val1[31:24] - val2[31:24]
\endcode
*/
uint32_t __USUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit unsigned saturating subtraction
\details This function enables you to perform four unsigned 8-bit integer subtractions, saturating
the results to the 8-bit unsigned integer range 0 \< x \< 28 - 1.
\param val1 first four 8-bit operands.
\param val2 second four 8-bit operands.
\returns
\li the subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par
The results are saturated to the 8-bit unsigned integer range 0 \< x \< 28 - 1.
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0]
res[15:8] = val1[15:8] - val2[15:8]
res[23:16] = val1[23:16] - val2[23:16]
res[31:24] = val1[31:24] - val2[31:24]
\endcode
*/
uint32_t __UQSUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Quad 8-bit unsigned subtraction with halved results
\details This function enables you to perform four unsigned 8-bit integer subtractions, halving the
results.
\param val1 first four 8-bit operands.
\param val2 second four 8-bit operands.
\returns
\li the halved subtraction of the first byte in the second operand from the first byte in the
first operand, in the first bytes of the return value.
\li the halved subtraction of the second byte in the second operand from the second byte in
the first operand, in the second byte of the return value.
\li the halved subtraction of the third byte in the second operand from the third byte in the
first operand, in the third byte of the return value.
\li the halved subtraction of the fourth byte in the second operand from the fourth byte in
the first operand, in the fourth byte of the return value.
\par Operation:
\code
res[7:0] = val1[7:0] - val2[7:0] >> 1
res[15:8] = val1[15:8] - val2[15:8] >> 1
res[23:16] = val1[23:16] - val2[23:16] >> 1
res[31:24] = val1[31:24] - val2[31:24] >> 1
\endcode
*/
uint32_t __UHSUB8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit signed addition
\details This function enables you to perform two 16-bit signed integer additions.
The GE bits in the APSR are set according to the results of the additions.
\param val1 first two 16-bit summands.
\param val2 second two 16-bit summands.
\returns
\li the addition of the low halfwords in the low halfword of the return value.
\li the addition of the high halfwords in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0]
res[31:16] = val1[31:16] + val2[31:16]
\endcode
*/
uint32_t __SADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit saturating addition
\details This function enables you to perform two 16-bit integer arithmetic additions in parallel,
saturating the results to the 16-bit signed integer range -215 \<= x \<= 215 - 1.
\param val1 first two 16-bit summands.
\param val2 second two 16-bit summands.
\returns
\li the saturated addition of the low halfwords, in the low halfword of the return value.
\li the saturated addition of the high halfwords, in the high halfword of the return value.
\par
The returned results are saturated to the 16-bit signed integer
range -215 \<= x \<= 215 - 1
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0]
res[31:16] = val1[31:16] + val2[31:16]
\endcode
*/
uint32_t __QADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed addition with halved results
\details This function enables you to perform two signed 16-bit integer additions, halving the
results.
\param val1 first two 16-bit summands.
\param val2 second two 16-bit summands.
\returns
\li the halved addition of the low halfwords, in the low halfword of the return value.
\li the halved addition of the high halfwords, in the high halfword of the return value.
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0] >> 1
res[31:16] = val1[31:16] + val2[31:16] >> 1
\endcode
*/
uint32_t __SHADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit unsigned addition
\details This function enables you to perform two 16-bit unsigned integer additions.
The GE bits in the APSR are set according to the results.
\param val1 first two 16-bit summands for each addition.
\param val2 second two 16-bit summands for each addition.
\returns
\li the addition of the low halfwords in each operand, in the low halfword of the
return value.
\li the addition of the high halfwords in each operand, in the high halfword of the
return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0x10000 then APSR.GE[0] = 11 else 00
\li if res[31:16] \>= 0x10000 then APSR.GE[1] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0]
res[31:16] = val1[31:16] + val2[31:16]
\endcode
*/
uint32_t __UADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned saturating addition
\details This function enables you to perform two unsigned 16-bit integer additions, saturating the
results to the 16-bit unsigned integer range 0 \< x \< 216 - 1.
\param val1 first two 16-bit summands.
\param val2 second two 16-bit summands.
\returns
\li the addition of the low halfword in the first operand and the low halfword in the
second operand, in the low halfword of the return value.
\li the addition of the high halfword in the first operand and the high halfword in the
second operand, in the high halfword of the return value.
\par
The results are saturated to the 16-bit unsigned integer
range 0 \< x \< 216 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0]
res[31:16] = val1[31:16] + val2[31:16]
\endcode
*/
uint32_t __UQADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned addition with halved results
\details This function enables you to perform two unsigned 16-bit integer additions, halving the
results.
\param val1 first two 16-bit summands.
\param val2 second two 16-bit summands.
\returns
\li the halved addition of the low halfwords in each operand, in the low halfword of
the return value.
\li the halved addition of the high halfwords in each operand, in the high halfword
of the return value.
\par Operation:
\code
res[15:0] = val1[15:0] + val2[15:0] >> 1
res[31:16] = val1[31:16] + val2[31:16] >> 1
\endcode
*/
uint32_t __UHADD16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit signed subtraction
\details This function enables you to perform two 16-bit signed integer subtractions.
The GE bits in the APSR are set according to the results.
\param val1 first two 16-bit operands of each subtraction.
\param val2 second two 16-bit operands of each subtraction.
\returns
\li the subtraction of the low halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the subtraction of the high halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \li res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0]
res[31:16] = val1[31:16] - val2[31:16]
\endcode
*/
uint32_t __SSUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit saturating subtract
\details This function enables you to perform two 16-bit integer subtractions, saturating the
results to the 16-bit signed integer range -215 \<= x \<= 215 - 1.
\param val1 first two 16-bit operands.
\param val2 second two 16-bit operands.
\returns
\li the saturated subtraction of the low halfword in the second operand from the low
halfword in the first operand, in the low halfword of the returned result.
\li the saturated subtraction of the high halfword in the second operand from the high
halfword in the first operand, in the high halfword of the returned result.
\par
The returned results are saturated to the 16-bit signed integer
range -215 \<= x \<= 215 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0]
res[31:16] = val1[31:16] - val2[31:16]
\endcode
*/
uint32_t __QSUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed subtraction with halved results
\details This function enables you to perform two signed 16-bit integer subtractions, halving the
results.
\param val1 first two 16-bit operands.
\param val2 second two 16-bit operands.
\returns
\li the halved subtraction of the low halfword in the second operand from the low
halfword in the first operand, in the low halfword of the returned result.
\li the halved subtraction of the high halfword in the second operand from the high
halfword in the first operand, in the high halfword of the returned result.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0] >> 1
res[31:16] = val1[31:16] - val2[31:16] >> 1
\endcode
*/
uint32_t __SHSUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit unsigned subtract
\details This function enables you to perform two 16-bit unsigned integer subtractions.
The GE bits in the APSR are set according to the results.
\param val1 first two 16-bit operands.
\param val2 second two 16-bit operands.
\returns
\li the subtraction of the low halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the subtraction of the high halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0]
res[31:16] = val1[31:16] - val2[31:16]
\endcode
*/
uint32_t __USUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned saturating subtraction
\details This function enables you to perform two unsigned 16-bit integer subtractions, saturating
the results to the 16-bit unsigned integer range 0 \< x \< 216 - 1.
\param val1 first two 16-bit operands for each subtraction.
\param val2 second two 16-bit operands for each subtraction.
\returns
\li the subtraction of the low halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the subtraction of the high halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
The results are saturated to the 16-bit unsigned integer range 0 \< x \< 216 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0]
res[31:16] = val1[31:16] - val2[31:16]
\endcode
*/
uint32_t __UQSUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned subtraction with halved results
\details This function enables you to perform two unsigned 16-bit integer subtractions, halving
the results.
\param val1 first two 16-bit operands.
\param val2 second two 16-bit operands.
\returns
\li the halved subtraction of the low halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the halved subtraction of the high halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[15:0] >> 1
res[31:16] = val1[31:16] - val2[31:16] >> 1
\endcode
*/
uint32_t __UHSUB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit addition and subtraction with exchange
\details This function inserts an SASX instruction into the instruction stream generated by the
compiler. It enables you to exchange the halfwords of the second operand, add the high
halfwords and subtract the low halfwords.
The GE bits in the APRS are set according to the results.
\param val1 first operand for the subtraction in the low halfword, and the
first operand for the addition in the high halfword.
\param val2 second operand for the subtraction in the high halfword, and the
second operand for the addition in the low halfword.
\returns
\li the subtraction of the high halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the addition of the high halfword in the first operand and the low halfword in the
second operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] - val2[31:16]
res[31:16] = val1[31:16] + val2[15:0]
\endcode
*/
uint32_t __SASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit add and subtract with exchange
\details This function enables you to exchange the halfwords of the one operand, then add the high
halfwords and subtract the low halfwords, saturating the results to the 16-bit signed
integer range -215 \<= x \<= 215 - 1.
\param val1 first operand for the subtraction in the low halfword, and the
first operand for the addition in the high halfword.
\param val2 second operand for the subtraction in the high halfword, and the
second operand for the addition in the low halfword.
\returns
\li the saturated subtraction of the high halfword in the second operand from the low
halfword in the first operand, in the low halfword of the return value.
\li the saturated addition of the high halfword in the first operand and the low
halfword in the second operand, in the high halfword of the return value.
\par
The returned results are saturated to the 16-bit signed integer
range -215 \<= x \<= 215 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[31:16]
res[31:16] = val1[31:16] + val2[15:0]
\endcode
*/
uint32_t __QASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed addition and subtraction with halved results
\details This function enables you to exchange the two halfwords of one operand, perform one
signed 16-bit integer addition and one signed 16-bit subtraction, and halve the results.
\param val1 first 16-bit operands.
\param val2 second 16-bit operands.
\returns
\li the halved subtraction of the high halfword in the second operand from the low
halfword in the first operand, in the low halfword of the return value.
\li the halved addition of the low halfword in the second operand and the high
halfword in the first operand, in the high halfword of the return value.
\par Operation:
\code
res[15:0] = (val1[15:0] - val2[31:16]) >> 1
res[31:16] = (val1[31:16] + val2[15:0] ) >> 1
\endcode
*/
uint32_t __SHASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit unsigned addition and subtraction with exchange
\details This function enables you to exchange the two halfwords of the second operand, add the
high halfwords and subtract the low halfwords.
The GE bits in the APSR are set according to the results.
\param val1 first operand for the subtraction in the low halfword, and the
first operand for the addition in the high halfword.
\param val2 second operand for the subtraction in the high halfword and the
second operand for the addition in the low halfword.
\returns
\li the subtraction of the high halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the addition of the high halfword in the first operand and the low halfword in the
second operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par If \em res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0x10000 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] - val2[31:16]
res[31:16] = val1[31:16] + val2[15:0]
\endcode
*/
uint32_t __UASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned saturating addition and subtraction with exchange
\details This function enables you to exchange the halfwords of the second operand and perform
one unsigned 16-bit integer addition and one unsigned 16-bit subtraction, saturating the
results to the 16-bit unsigned integer range 0 \<= x \<= 216 - 1.
\param val1 first two 16-bit operands.
\param val2 second two 16-bit operands.
\returns
\li the subtraction of the high halfword in the second operand from the low halfword
in the first operand, in the low halfword of the return value.
\li the subtraction of the low halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
The results are saturated to the 16-bit unsigned integer
range 0 \<= x \<= 216 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] - val2[31:16]
res[31:16] = val1[31:16] + val2[15:0]
\endcode
*/
uint32_t __UQASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned addition and subtraction with halved results and exchange
\details This function enables you to exchange the halfwords of the second operand, add the high
halfwords and subtract the low halfwords, halving the results.
\param val1 first operand for the subtraction in the low halfword, and the
first operand for the addition in the high halfword.
\param val2 second operand for the subtraction in the high halfword, and the
second operand for the addition in the low halfword.
\returns
\li the halved subtraction of the high halfword in the second operand from the low
halfword in the first operand.
\li the halved addition of the high halfword in the first operand and the low halfword
in the second operand.
\par Operation:
\code
res[15:0] = (val1[15:0] - val2[31:16]) >> 1
res[31:16] = (val1[31:16] + val2[15:0] ) >> 1
\endcode
*/
uint32_t __UHASX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit signed subtraction and addition with exchange
\details This function enables you to exchange the two halfwords of one operand and perform one
16-bit integer subtraction and one 16-bit addition.
The GE bits in the APSR are set according to the results.
\param val1 first operand for the addition in the low halfword, and the first
operand for the subtraction in the high halfword.
\param val2 second operand for the addition in the high halfword, and the
second operand for the subtraction in the low halfword.
\returns
\li the addition of the low halfword in the first operand and the high halfword in the
second operand, in the low halfword of the return value.
\li the subtraction of the low halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] + val2[31:16]
res[31:16] = val1[31:16] - val2[15:0]
\endcode
*/
uint32_t __SSAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit subtract and add with exchange
\details This function enables you to exchange the halfwords of one operand, then subtract the
high halfwords and add the low halfwords, saturating the results to the 16-bit signed
integer range -215 \<= x \<= 215 - 1.
\param val1 first operand for the addition in the low halfword, and the first
operand for the subtraction in the high halfword.
\param val2 second operand for the addition in the high halfword, and the
second operand for the subtraction in the low halfword.
\returns
\li the saturated addition of the low halfword of the first operand and the high
halfword of the second operand, in the low halfword of the return value.
\li the saturated subtraction of the low halfword of the second operand from the high
halfword of the first operand, in the high halfword of the return value.
\par
The returned results are saturated to the 16-bit signed integer
range -215 \<= x \<= 215 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] + val2[31:16]
res[31:16] = val1[31:16] - val2[15:0]
\endcode
*/
uint32_t __QSAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed subtraction and addition with halved results
\details This function enables you to exchange the two halfwords of one operand, perform one
signed 16-bit integer subtraction and one signed 16-bit addition, and halve the results.
\param val1 first 16-bit operands.
\param val2 second 16-bit operands.
\returns
\li the halved addition of the low halfword in the first operand and the high halfword
in the second operand, in the low halfword of the return value.
\li the halved subtraction of the low halfword in the second operand from the high
halfword in the first operand, in the high halfword of the return value.
\par Operation:
\code
res[15:0] = (val1[15:0] + val2[31:16]) >> 1
res[31:16] = (val1[31:16] - val2[15:0] ) >> 1
\endcode
*/
uint32_t __SHSAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief GE setting dual 16-bit unsigned subtract and add with exchange
\details This function enables you to exchange the halfwords of the second operand, subtract the
high halfwords and add the low halfwords.
The GE bits in the APSR are set according to the results.
\param val1 first operand for the addition in the low halfword, and the first
operand for the subtraction in the high halfword.
\param val2 second operand for the addition in the high halfword, and the
second operand for the subtraction in the low halfword.
\returns
\li the addition of the low halfword in the first operand and the high halfword in the
second operand, in the low halfword of the return value.
\li the subtraction of the low halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
Each bit in APSR.GE is set or cleared for each byte in the return value, depending on
the results of the operation.
\par
If \em res is the return value, then:
\li if res[15:0] \>= 0x10000 then APSR.GE[1:0] = 11 else 00
\li if res[31:16] \>= 0 then APSR.GE[3:2] = 11 else 00
\par Operation:
\code
res[15:0] = val1[15:0] + val2[31:16]
res[31:16] = val1[31:16] - val2[15:0]
\endcode
*/
uint32_t __USAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned saturating subtraction and addition with exchange
\details This function enables you to exchange the halfwords of the second operand and perform
one unsigned 16-bit integer subtraction and one unsigned 16-bit addition, saturating the
results to the 16-bit unsigned integer range 0 \<= x \<= 216 - 1.
\param val1 first 16-bit operand for the addition in the low halfword, and the
first 16-bit operand for the subtraction in the high halfword.
\param val2 second 16-bit halfword for the addition in the high halfword,
and the second 16-bit halfword for the subtraction in the low halfword.
\returns
\li the addition of the low halfword in the first operand and the high halfword in the
second operand, in the low halfword of the return value.
\li the subtraction of the low halfword in the second operand from the high halfword
in the first operand, in the high halfword of the return value.
\par
The results are saturated to the 16-bit unsigned integer
range 0 \<= x \<= 216 - 1.
\par Operation:
\code
res[15:0] = val1[15:0] + val2[31:16]
res[31:16] = val1[31:16] - val2[15:0]
\endcode
*/
uint32_t __UQSAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit unsigned subtraction and addition with halved results and exchange
\details This function enables you to exchange the halfwords of the second operand, subtract the
high halfwords and add the low halfwords, halving the results.
\param val1 first operand for the addition in the low halfword, and the first
operand for the subtraction in the high halfword.
\param val2 second operand for the addition in the high halfword, and the
second operand for the subtraction in the low halfword.
\returns
\li the halved addition of the high halfword in the second operand and the low
halfword in the first operand, in the low halfword of the return value.
\li the halved subtraction of the low halfword in the second operand from the high
halfword in the first operand, in the high halfword of the return value.
\par Operation:
\code
res[15:0] = (val1[15:0] + val2[31:16]) >> 1
res[31:16] = (val1[31:16] - val2[15:0] ) >> 1
\endcode
*/
uint32_t __UHSAX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Unsigned sum of quad 8-bit unsigned absolute difference
\details This function enables you to perform four unsigned 8-bit subtractions, and add the
absolute values of the differences together, returning the result as a single unsigned
integer.
\param val1 first four 8-bit operands for the subtractions.
\param val2 second four 8-bit operands for the subtractions.
\returns
\li the subtraction of the first byte in the second operand from the first byte in the
first operand.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand.
\par
The sum is returned as a single unsigned integer.
\par Operation:
\code
absdiff1 = val1[7:0] - val2[7:0]
absdiff2 = val1[15:8] - val2[15:8]
absdiff3 = val1[23:16] - val2[23:16]
absdiff4 = val1[31:24] - val2[31:24]
res[31:0] = absdiff1 + absdiff2 + absdiff3 + absdiff4
\endcode
*/
uint32_t __USAD8(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Unsigned sum of quad 8-bit unsigned absolute difference with 32-bit accumulate
\details This function enables you to perform four unsigned 8-bit subtractions, and add the
absolute values of the differences to a 32-bit accumulate operand.
\param val1 first four 8-bit operands for the subtractions.
\param val2 second four 8-bit operands for the subtractions.
\param val3 accumulation value.
\returns
the sum of the absolute differences of the following
bytes, added to the accumulation value:
\li the subtraction of the first byte in the second operand from the first byte in the
first operand.
\li the subtraction of the second byte in the second operand from the second byte in
the first operand.
\li the subtraction of the third byte in the second operand from the third byte in the
first operand.
\li the subtraction of the fourth byte in the second operand from the fourth byte in
the first operand.
\par Operation:
\code
absdiff1 = val1[7:0] - val2[7:0]
absdiff2 = val1[15:8] - val2[15:8]
absdiff3 = val1[23:16] - val2[23:16]
absdiff4 = val1[31:24] - val2[31:24]
sum = absdiff1 + absdiff2 + absdiff3 + absdiff4
res[31:0] = sum[31:0] + val3[31:0]
\endcode
*/
uint32_t __USADA8(uint32_t val1, uint32_t val2, uint32_t val3);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit saturate
\details This function enables you to saturate two signed 16-bit values to a selected signed range.
The Q bit is set if either operation saturates.
\param val1 two signed 16-bit values to be saturated.
\param val2 bit position for saturation, an integral constant expression in the
range 1 to 16.
\returns
the sum of the absolute differences of the following
bytes, added to the accumulation value:
\li the signed saturation of the low halfword in \em val1, saturated to the bit position
specified in \em val2 and returned in the low halfword of the return value.
\li the signed saturation of the high halfword in val1, saturated to the bit position
specified in val2 and returned in the high halfword of the return value.
\par Operation:
\code
Saturate halfwords in val1 to the signed range specified by the bit position in val2
\endcode
*/
uint32_t __SSAT16(uint32_t val1, const uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit unsigned saturate
\details This function enables you to saturate two signed 16-bit values to a selected unsigned
range.
The Q bit is set if either operation saturates.
\param val1 two 16-bit values that are to be saturated.
\param val2 bit position for saturation, and must be an integral constant
expression in the range 0 to 15.
\returns
the saturation of the two signed 16-bit values, as non-negative values.
\li the saturation of the low halfword in \em val1, saturated to the bit position
specified in \em val2 and returned in the low halfword of the return value.
\li the saturation of the high halfword in \em val1, saturated to the bit position
specified in \em val2 and returned in the high halfword of the return value.
\par Operation:
\code
Saturate halfwords in val1 to the unsigned range specified by the bit position in val2
\endcode
*/
uint32_t __USAT16(uint32_t val1, const uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual extract 8-bits and zero-extend to 16-bits
\details This function enables you to extract two 8-bit values from an operand and zero-extend
them to 16 bits each.
\param val two 8-bit values in val[7:0] and val[23:16] to be sign-extended.
\returns
the 8-bit values zero-extended to 16-bit values.
\li zero-extended value of val[7:0] in the low halfword of the return value.
\li zero-extended value of val[23:16] in the high halfword of the return value.
\par Operation:
\code
res[15:0] = ZeroExtended(val[7:0] )
res[31:16] = ZeroExtended(val[23:16])
\endcode
*/
uint32_t __UXTB16(uint32_t val);
/**************************************************************************************************/
/**
\brief Extracted 16-bit to 32-bit unsigned addition
\details This function enables you to extract two 8-bit values from one operand, zero-extend them
to 16 bits each, and add the results to two 16-bit values from another operand.
\param val1 value added to the zero-extended to 16-bit values.
\param val2 two 8-bit values to be extracted and zero-extended.
\returns
the 8-bit values in \em val2, zero-extended to 16-bit values
and added to \em val1.
\par Operation:
\code
res[15:0] = ZeroExt(val2[7:0] to 16 bits) + val1[15:0]
res[31:16] = ZeroExt(val2[31:16] to 16 bits) + val1[31:16]
\endcode
*/
uint32_t __UXTAB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual extract 8-bits and sign extend each to 16-bits
\details This function enables you to extract two 8-bit values from an operand and sign-extend
them to 16 bits each.
\param val two 8-bit values in val[7:0] and val[23:16] to be sign-extended.
\returns
the 8-bit values sign-extended to 16-bit values.
\li sign-extended value of val[7:0] in the low halfword of the return value.
\li sign-extended value of val[23:16] in the high halfword of the return value.
\par Operation:
\code
res[15:0] = SignExtended(val[7:0]
res[31:16] = SignExtended(val[23:16]
\endcode
*/
uint32_t __SXTB16(uint32_t val);
/**************************************************************************************************/
/**
\brief Rotate right, dual extract 8-bits and sign extend each to 16-bits
\details This function enables you to rotate an operand by 8/16/24 bit, extract two 8-bit values and sign-extend
them to 16 bits each.
\param val two 8-bit values in val[7:0] and val[23:16] to be sign-extended.
\param rotate number of bits to rotate val. Only 8,16 and 24 are accepted
\returns
the 8-bit values sign-extended to 16-bit values.
\li sign-extended value of val[7:0] in the low halfword of the return value.
\li sign-extended value of val[23:16] in the high halfword of the return value.
\par Operation:
\code
val = Rotate(val, rotate)
res[15:0] = SignExtended(val[7:0])
res[31:16] = SignExtended(val[23:16])
\endcode
*/
uint32_t __SXTB16_RORn(uint32_t val, uint32_r rotate);
/**************************************************************************************************/
/**
\brief Dual extracted 8-bit to 16-bit signed addition
\details This function enables you to extract two 8-bit values from the second operand (at bit
positions [7:0] and [23:16]), sign-extend them to 16-bits each, and add the results to the
first operand.
\param val1 values added to the zero-extended to 16-bit values.
\param val2 two 8-bit values to be extracted and zero-extended.
\returns
the addition of \em val1 and \em val2, where the 8-bit values in
val2[7:0] and val2[23:16] have been extracted and sign-extended prior to the addition.
\par Operation:
\code
res[15:0] = val1[15:0] + SignExtended(val2[7:0])
res[31:16] = val1[31:16] + SignExtended(val2[23:16])
\endcode
*/
uint32_t __SXTAB16(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting sum of dual 16-bit signed multiply
\details This function enables you to perform two 16-bit signed multiplications, adding the
products together.
The Q bit is set if the addition overflows.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\returns
the sum of the products of the two 16-bit signed multiplications.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
res[31:0] = p1 + p2
\endcode
*/
uint32_t __SMUAD(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting sum of dual 16-bit signed multiply with exchange
\details This function enables you to perform two 16-bit signed multiplications with exchanged
halfwords of the second operand, adding the products together.
The Q bit is set if the addition overflows.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\returns
the sum of the products of the two 16-bit signed multiplications with exchanged
halfwords of the second operand.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
res[31:0] = p1 + p2
\endcode
*/
uint32_t __SMUADX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief 32-bit signed multiply with 32-bit truncated accumulator.
\details This function enables you to perform a signed 32-bit multiplications, adding the most significant 32 bits
of the 64-bit result to a 32-bit accumulate operand.
\param val1 first operand for multiplication.
\param val2 second operand for multiplication.
\param val3 accumulate value.
\returns the product of multiplication (most significant 32 bits) is added to the accumulate
value, as a 32-bit integer.
\par Operation:
\code
p = val1 * val2
res[31:0] = p[61:32] + val3[31:0]
\endcode
*/
uint32_t __SMMLA (int32_t val1, int32_t val2, int32_t val3);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit signed multiply with single 32-bit accumulator
\details This function enables you to perform two signed 16-bit multiplications, adding both
results to a 32-bit accumulate operand.
The Q bit is set if the addition overflows. Overflow cannot occur during the multiplications.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the product of each multiplication added to the accumulate
value, as a 32-bit integer.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
res[31:0] = p1 + p2 + val3[31:0]
\endcode
*/
uint32_t __SMLAD(uint32_t val1, uint32_t val2, uint32_t val3);
/**************************************************************************************************/
/**
\brief Q setting pre-exchanged dual 16-bit signed multiply with single 32-bit accumulator
\details This function enables you to perform two signed 16-bit multiplications with exchanged
halfwords of the second operand, adding both results to a 32-bit accumulate operand.
The Q bit is set if the addition overflows. Overflow cannot occur during the multiplications.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the product of each multiplication with exchanged
halfwords of the second operand added to the accumulate value, as a 32-bit integer.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
res[31:0] = p1 + p2 + val3[31:0]
\endcode
*/
uint32_t __SMLADX(uint32_t val1, uint32_t val2, uint32_t val3);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed multiply with single 64-bit accumulator
\details This function enables you to perform two signed 16-bit multiplications, adding both
results to a 64-bit accumulate operand. Overflow is only possible as a result of the 64-bit
addition. This overflow is not detected if it occurs. Instead, the result wraps around
modulo264.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the product of each multiplication added to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
sum = p1 + p2 + val3[63:32][31:0]
res[63:32] = sum[63:32]
res[31:0] = sum[31:0]
\endcode
*/
uint64_t __SMLALD(uint32_t val1, uint32_t val2, uint64_t val3);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed multiply with exchange with single 64-bit accumulator
\details This function enables you to exchange the halfwords of the second operand, and perform
two signed 16-bit multiplications, adding both results to a 64-bit accumulate operand.
Overflow is only possible as a result of the 64-bit addition. This overflow is not detected
if it occurs. Instead, the result wraps around modulo264.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the product of each multiplication added to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
sum = p1 + p2 + val3[63:32][31:0]
res[63:32] = sum[63:32]
res[31:0] = sum[31:0]
\endcode
*/
unsigned long long __SMLALDX(uint32_t val1, uint32_t val2, unsigned long long val3);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed multiply returning difference
\details This function enables you to perform two 16-bit signed multiplications, taking the
difference of the products by subtracting the high halfword product from the low
halfword product.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\returns
the difference of the products of the two 16-bit signed multiplications.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
res[31:0] = p1 - p2
\endcode
*/
uint32_t __SMUSD(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Dual 16-bit signed multiply with exchange returning difference
\details This function enables you to perform two 16-bit signed multiplications, subtracting one
of the products from the other. The halfwords of the second operand are exchanged
before performing the arithmetic. This produces top * bottom and bottom * top
multiplication.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\returns
the difference of the products of the two 16-bit signed multiplications.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
res[31:0] = p1 - p2
\endcode
*/
uint32_t __SMUSDX(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit signed multiply subtract with 32-bit accumulate
\details This function enables you to perform two 16-bit signed multiplications, take the
difference of the products, subtracting the high halfword product from the low halfword
product, and add the difference to a 32-bit accumulate operand.
The Q bit is set if the accumulation overflows. Overflow cannot occur during the multiplications or the
subtraction.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the difference of the product of each multiplication, added
to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
res[31:0] = p1 - p2 + val3[31:0]
\endcode
*/
uint32_t __SMLSD(uint32_t val1, uint32_t val2, uint32_t val3);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit signed multiply with exchange subtract with 32-bit accumulate
\details This function enables you to exchange the halfwords in the second operand, then perform
two 16-bit signed multiplications. The difference of the products is added to a 32-bit
accumulate operand.
The Q bit is set if the addition overflows. Overflow cannot occur during the multiplications or the subtraction.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the difference of the product of each multiplication, added
to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
res[31:0] = p1 - p2 + val3[31:0]
\endcode
*/
uint32_t __SMLSDX(uint32_t val1, uint32_t val2, uint32_t val3);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit signed multiply subtract with 64-bit accumulate
\details This function It enables you to perform two 16-bit signed multiplications, take the
difference of the products, subtracting the high halfword product from the low halfword
product, and add the difference to a 64-bit accumulate operand. Overflow cannot occur
during the multiplications or the subtraction. Overflow can occur as a result of the 64-bit
addition, and this overflow is not detected. Instead, the result wraps round to
modulo264.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the difference of the product of each multiplication,
added to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[15:0]
p2 = val1[31:16] * val2[31:16]
res[63:0] = p1 - p2 + val3[63:0]
\endcode
*/
uint64_t __SMLSLD(uint32_t val1, uint32_t val2, uint64_t val3);
/**************************************************************************************************/
/**
\brief Q setting dual 16-bit signed multiply with exchange subtract with 64-bit accumulate
\details This function enables you to exchange the halfwords of the second operand, perform two
16-bit multiplications, adding the difference of the products to a 64-bit accumulate
operand. Overflow cannot occur during the multiplications or the subtraction. Overflow
can occur as a result of the 64-bit addition, and this overflow is not detected. Instead,
the result wraps round to modulo264.
\param val1 first 16-bit operands for each multiplication.
\param val2 second 16-bit operands for each multiplication.
\param val3 accumulate value.
\returns
the difference of the product of each multiplication,
added to the accumulate value.
\par Operation:
\code
p1 = val1[15:0] * val2[31:16]
p2 = val1[31:16] * val2[15:0]
res[63:0] = p1 - p2 + val3[63:0]
\endcode
*/
unsigned long long __SMLSLDX(uint32_t val1, uint32_t val2, unsigned long long val3);
/**************************************************************************************************/
/**
\brief Select bytes based on GE bits
\details This function inserts a SEL instruction into the instruction stream generated by the
compiler. It enables you to select bytes from the input parameters, whereby the bytes
that are selected depend upon the results of previous SIMD instruction function. The
results of previous SIMD instruction function are represented by the Greater than or
Equal flags in the Application Program Status Register (APSR).
The __SEL function works equally well on both halfword and byte operand function
results. This is because halfword operand operations set two (duplicate) GE bits per
value.
\param val1 four selectable 8-bit values.
\param val2 four selectable 8-bit values.
\returns
The function selects bytes from the input parameters and returns them in the
return value, res, according to the following criteria:
\li if APSR.GE[0] == 1 then res[7:0] = val1[7:0] else res[7:0] = val2[7:0]
\li if APSR.GE[1] == 1 then res[15:8] = val1[15:8] else res[15:8] = val2[15:8]
\li if APSR.GE[2] == 1 then res[23:16] = val1[23:16] else res[23:16] = val2[23:16]
\li if APSR.GE[3] == 1 then res[31;24] = val1[31:24] else res = val2[31:24]
*/
uint32_t __SEL(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting saturating add
\details This function enables you to obtain the saturating add of two integers.
The Q bit is set if the operation saturates.
\param val1 first summand of the saturating add operation.
\param val2 second summand of the saturating add operation.
\returns
the saturating addition of val1 and val2.
\par Operation:
\code
res[31:0] = SAT(val1 + SAT(val2))
\endcode
*/
uint32_t __QADD(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Q setting saturating subtract
\details This function enables you to obtain the saturating subtraction of two integers.
The Q bit is set if the operation saturates.
\param val1 minuend of the saturating subtraction operation.
\param val2 subtrahend of the saturating subtraction operation.
\returns
the saturating subtraction of val1 and val2.
\par Operation:
\code
res[31:0] = SAT(val1 - SAT(val2))
\endcode
*/
uint32_t __QSUB(uint32_t val1, uint32_t val2);
/**************************************************************************************************/
/**
\brief Halfword packing instruction. Combines bits[15:0] of val1
with bits[31:16] of val2 levitated with the val3.
\details Combine a halfword from one register with a halfword from another register.
The second argument can be left-shifted before extraction of the halfword. The registers
PC and SP are not allowed as arguments. This instruction does not change the flags.
\param val1 first 16-bit operands
\param val2 second 16-bit operands
\param val3 value for left-shifting val2. Value range [0..31].
\returns
the combination of halfwords.
\par Operation:
\code
res[15:0] = val1[15:0]
res[31:16] = val2[31:16]<val1
with bits[15:0] of val2 right-shifted with the val3.
\details Combines a halfword from one register with a halfword from another register.
The second argument can be right-shifted before extraction of the halfword. The registers
PC and SP are not allowed as arguments. This instruction does not change the flags.
\param val1 second 16-bit operands
\param val2 first 16-bit operands
\param val3 value for right-shifting val2. Value range [1..32].
\returns
the combination of halfwords.
\par Operation:
\code
res[15:0] = val2[15:0]>>val3
res[31:16] = val1[31:16]
\endcode
*/
uint32_t __PKHTB(uint32_t val1, uint32_t val2, uint32_t val3);
/** @} */ /* end group intrinsic_SIMD_gr */