From 4afe2e88e7bec8f74fc8cd14cf87563783c41cba Mon Sep 17 00:00:00 2001
From: Manuel Caroli <Manuel.Caroli@sophia.inria.fr>
Date: Fri, 23 Oct 2009 09:56:56 +0000
Subject: [PATCH] add a phrase that precises that input points have to lie
 inside the cube

---
 .../doc_tex/Periodic_3_triangulation_3/P3Triang3.tex          | 4 +++-
 1 file changed, 3 insertions(+), 1 deletion(-)

diff --git a/Periodic_3_triangulation_3/doc_tex/Periodic_3_triangulation_3/P3Triang3.tex b/Periodic_3_triangulation_3/doc_tex/Periodic_3_triangulation_3/P3Triang3.tex
index 43dbe2e94ae..b7a0995fc7c 100644
--- a/Periodic_3_triangulation_3/doc_tex/Periodic_3_triangulation_3/P3Triang3.tex
+++ b/Periodic_3_triangulation_3/doc_tex/Periodic_3_triangulation_3/P3Triang3.tex
@@ -42,7 +42,9 @@ $[\alpha,\alpha+c)\times[\beta,\beta+c)\times[\gamma,\gamma+c)$
 contains exactly one representative of each element in $\mathbb
 T_c^3$. We call it \emph{original domain}. From now on, when we talk
 about \textit{points}, we generally mean representatives of elements
-of $\mathbb T_c^3$ that lie inside the original domain.
+of $\mathbb T_c^3$ that lie inside the original domain. Note that any
+input point is required to be an element of the half-open cube
+representing the original domain as defined above.
 
 There are simplices containing points inside the original domain but
 also points outside it. The points outside the original domain are