@@ -121,7 +121,7 @@ DEF_HELPER_FLAGS_5(sme_addha_d, TCG_CALL_NO_RWG, void, ptr, ptr, ptr, ptr, i32)
DEF_HELPER_FLAGS_5(sme_addva_d, TCG_CALL_NO_RWG, void, ptr, ptr, ptr, ptr, i32)
DEF_HELPER_FLAGS_7(sme_fmopa_h, TCG_CALL_NO_RWG,
- void, ptr, ptr, ptr, ptr, ptr, ptr, i32)
+ void, env, ptr, ptr, ptr, ptr, ptr, i32)
DEF_HELPER_FLAGS_7(sme_fmopa_s, TCG_CALL_NO_RWG,
void, ptr, ptr, ptr, ptr, ptr, ptr, i32)
DEF_HELPER_FLAGS_7(sme_fmopa_d, TCG_CALL_NO_RWG,
@@ -992,12 +992,23 @@ static inline uint32_t f16mop_adj_pair(uint32_t pair, uint32_t pg, uint32_t neg)
}
static float32 f16_dotadd(float32 sum, uint32_t e1, uint32_t e2,
- float_status *s_std, float_status *s_odd)
+ float_status *s_f16, float_status *s_std,
+ float_status *s_odd)
{
- float64 e1r = float16_to_float64(e1 & 0xffff, true, s_std);
- float64 e1c = float16_to_float64(e1 >> 16, true, s_std);
- float64 e2r = float16_to_float64(e2 & 0xffff, true, s_std);
- float64 e2c = float16_to_float64(e2 >> 16, true, s_std);
+ /*
+ * We need three different float_status for different parts of this
+ * operation:
+ * - the input conversion of the float16 values must use the
+ * f16-specific float_status, so that the FPCR.FZ16 control is applied
+ * - operations on float32 including the final accumulation must use
+ * the normal float_status, so that FPCR.FZ is applied
+ * - we have pre-set-up copy of s_std which is set to round-to-odd,
+ * for the multiply (see below)
+ */
+ float64 e1r = float16_to_float64(e1 & 0xffff, true, s_f16);
+ float64 e1c = float16_to_float64(e1 >> 16, true, s_f16);
+ float64 e2r = float16_to_float64(e2 & 0xffff, true, s_f16);
+ float64 e2c = float16_to_float64(e2 >> 16, true, s_f16);
float64 t64;
float32 t32;
@@ -1018,21 +1029,25 @@ static float32 f16_dotadd(float32 sum, uint32_t e1, uint32_t e2,
return float32_add(sum, t32, s_std);
}
-void HELPER(sme_fmopa_h)(void *vza, void *vzn, void *vzm, void *vpn,
- void *vpm, void *vst, uint32_t desc)
+void HELPER(sme_fmopa_h)(CPUARMState *env,
+ void *vza, void *vzn, void *vzm, void *vpn,
+ void *vpm, uint32_t desc)
{
intptr_t row, col, oprsz = simd_maxsz(desc);
uint32_t neg = simd_data(desc) * 0x80008000u;
uint16_t *pn = vpn, *pm = vpm;
- float_status fpst_odd, fpst_std;
+ float_status fpst_odd, fpst_std, fpst_f16;
/*
- * Make a copy of float_status because this operation does not
- * update the cumulative fp exception status. It also produces
- * default nans. Make a second copy with round-to-odd -- see above.
+ * Make copies of fp_status and fp_status_f16, because this operation
+ * does not update the cumulative fp exception status. It also
+ * produces default NaNs. We also need a second copy of fp_status with
+ * round-to-odd -- see above.
*/
- fpst_std = *(float_status *)vst;
+ fpst_f16 = env->vfp.fp_status_f16;
+ fpst_std = env->vfp.fp_status;
set_default_nan_mode(true, &fpst_std);
+ set_default_nan_mode(true, &fpst_f16);
fpst_odd = fpst_std;
set_float_rounding_mode(float_round_to_odd, &fpst_odd);
@@ -1052,7 +1067,8 @@ void HELPER(sme_fmopa_h)(void *vza, void *vzn, void *vzm, void *vpn,
uint32_t m = *(uint32_t *)(vzm + H1_4(col));
m = f16mop_adj_pair(m, pcol, 0);
- *a = f16_dotadd(*a, n, m, &fpst_std, &fpst_odd);
+ *a = f16_dotadd(*a, n, m,
+ &fpst_f16, &fpst_std, &fpst_odd);
}
col += 4;
pcol >>= 4;
@@ -326,8 +326,29 @@ static bool do_outprod_fpst(DisasContext *s, arg_op *a, MemOp esz,
return true;
}
-TRANS_FEAT(FMOPA_h, aa64_sme, do_outprod_fpst, a,
- MO_32, FPST_FPCR_F16, gen_helper_sme_fmopa_h)
+static bool do_outprod_env(DisasContext *s, arg_op *a, MemOp esz,
+ gen_helper_gvec_5_ptr *fn)
+{
+ int svl = streaming_vec_reg_size(s);
+ uint32_t desc = simd_desc(svl, svl, a->sub);
+ TCGv_ptr za, zn, zm, pn, pm;
+
+ if (!sme_smza_enabled_check(s)) {
+ return true;
+ }
+
+ za = get_tile(s, esz, a->zad);
+ zn = vec_full_reg_ptr(s, a->zn);
+ zm = vec_full_reg_ptr(s, a->zm);
+ pn = pred_full_reg_ptr(s, a->pn);
+ pm = pred_full_reg_ptr(s, a->pm);
+
+ fn(tcg_env, za, zn, zm, pn, pm, tcg_constant_i32(desc));
+ return true;
+}
+
+TRANS_FEAT(FMOPA_h, aa64_sme, do_outprod_env, a,
+ MO_32, gen_helper_sme_fmopa_h)
TRANS_FEAT(FMOPA_s, aa64_sme, do_outprod_fpst, a,
MO_32, FPST_FPCR, gen_helper_sme_fmopa_s)
TRANS_FEAT(FMOPA_d, aa64_sme_f64f64, do_outprod_fpst, a,
The FMOPA (widening) SME instruction takes pairs of half-precision floating point values, widens them to single-precision, does a two-way dot product and accumulates the results into a single-precision destination. We don't quite correctly handle the FPCR bits FZ and FZ16 which control flushing of denormal inputs and outputs. This is because at the moment we pass a single float_status value to the helper function, which then uses that configuration for all the fp operations it does. However, because the inputs to this operation are float16 and the outputs are float32 we need to use the fp_status_f16 for the float16 input widening but the normal fp_status for everything else. Otherwise we will apply the flushing control FPCR.FZ16 to the 32-bit output rather than the FPCR.FZ control, and incorrectly flush a denormal output to zero when we should not (or vice-versa). Pass the CPU env to the sme_fmopa_h helper instead of an fp_status pointer, and have the helper pass an extra fp_status into the f16_dotadd() function so that we can use the right status for the right parts of this operation. Cc: qemu-stable@nongnu.org Signed-off-by: Peter Maydell <peter.maydell@linaro.org> --- NB that there's only one user of do_outprod_env() right now, but we're going to want it also for implementing FEAT_EBF16, because that will mean that the sma_bfmopa helper also wants to be passed an env pointer. --- target/arm/tcg/helper-sme.h | 2 +- target/arm/tcg/sme_helper.c | 42 +++++++++++++++++++++++----------- target/arm/tcg/translate-sme.c | 25 ++++++++++++++++++-- 3 files changed, 53 insertions(+), 16 deletions(-)